Impact of Climate Change on Groundwater...
Transcript of Impact of Climate Change on Groundwater...
Université de Liège Faculté des Sciences Appliquées
Département ArGEnCo Architecture, Géologie, Environnement et Constructions
Secteur GEO³ Géotechnologies, Hydrogéologie, Prospection Géophysique
Impact of Climate Change on Groundwater Reserves
by Pascal GODERNIAUX
Thesis presented to the University of Liège in fulfilment of the requirements for the degree of
"Docteur en Sciences de l'Ingénieur"
January 2010
This research was carried out by: Pascal GODERNIAUX Research Fellow ("Aspirant du FNRS") Hydrogeology and Environmental Geology Group ArGEnCo Department University of Liège (ULg) Chemin des Chevreuils, 1 Building B52 4000 Liège BELGIUM
This research was financed by: Fonds de la Recherche Scientifique – FNRS (Funds for Scientific Research – FNRS) Rue d'Egmont, 5 1000 Bruxelles BELGIUM
Board of examiners composed of: Prof. CHARLIER Robert, Université de Liège (Belgium) – President Prof. DASSARGUES Alain, Université de Liège (Belgium) – Supervisor Dr. BROUYERE Serge, Université de Liège (Belgium) – Co-supervisor Prof. PIROTTON Michel, Université de Liège (Belgium) Dr. BLENKINSOP Stephen, Newcastle University (United Kingdom) Prof. THERRIEN René, Université Laval (Canada) Prof. VANCLOOSTER Marnik, Université Catholique de Louvain (Belgium)
Citation: Goderniaux P., 2010. Impact of Climate Change on Groundwater Reserves. PhD Thesis. University of Liège, Faculty of Applied Sciences. Liège, Belgium. pp. 190.
Summary
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SUMMARY
Estimating the impacts of climate change on groundwater represents one of the most difficult
challenges faced by water resources specialists. One difficulty is that simplifying the
representation of the hydrological system, or using too simple climate change scenarios often
leads to discrepancies in projections. Additionally, these projections are affected by uncertainties
from various sources, and these uncertainties are not evaluated in previous studies. In this
context, the objective of this study is to provide an improved methodology for the estimation of
climate change impact on groundwater reserves, including the evaluation of uncertainties. This
methodology is applied to the case of the Geer basin catchment (480 km²) in Belgium.
A physically-based surface-subsurface flow model has been developed for the Geer basin with
the finite element model HydroGeoSphere. The simultaneous solution of surface and subsurface
flow equations in HydroGeoSphere, as well as the internal calculation of the actual
evapotranspiration as a function of the soil moisture at each node of the defined evaporative
zone, improve the representation and calibration of interdependent processes like recharge,
which is crucial in the context of climate change. Fully-integrated surface-subsurface flow models
have recently gained attention, but have not been used in the context of climate change impact
studies.
This surface-subsurface flow model is combined with advanced climate change scenarios for the
Geer basin. Climate change simulations were obtained from six regional climate model (RCM)
scenarios assuming the SRES A2 greenhouse gases emission (medium-high) scenario. These
RCM scenarios were statistically downscaled using two different methods: the 'Quantile Mapping
Biased Correction' technique and a 'Weather Generator' technique. Both of them are part of the
most advanced downscaling techniques. They are able to apply corrections not only to the mean
of climatic variables, but also across the statistical distributions of these variables. This is
Summary
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important as these distributions are expected to change in the future, with more violent rainfall
events, separated by longer dry periods. The 'quantile mapping bias-correction' technique
generate climate change time series representative of a stationary climate for the periods 2011-
2040, 2041-2070 and 2071-2100. The 'CRU' weather generator is used to generate a large number
of equiprobable scenarios simulating full transient climate change between 2010 and 2085. All
these scenarios are applied as input of the Geer basin model.
The uncertainty is evaluated from different possible sources. Using a multi-model ensemble of
RCMs and GCMs enables to evaluate the uncertainty linked to climatic models. The application
of a large number of equiprobable climate change scenarios, generated with the 'weather
generator', as input of the hydrological model allows assessing the uncertainty linked to the
natural variability of the weather. Finally, the uncertainty linked to the calibration of the
hydrological model is evaluated using the computer code 'UCODE_2005'.
The climate change scenarios for the Geer basin model predict hotter and drier summers and
warmer and wetter winters. Considering the results of this study, it is very likely that groundwater
levels and surface flow rates in the Geer basin will decrease. This is of concern because it also
means that groundwater quantities available for abstraction will also decrease. However, this
study also shows that the uncertainty surrounding these projections is relatively large and that it
remains difficult to state on the intensity of the decrease.
Keywords: Groundwater, Climate change, Geer basin, Chalk, Integrated model,
HydroGeoSphere, Uncertainty, Stochastic scenarios, Weather generator, UCODE_2005.
Acknowledgements
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ACKNOWLEDGEMENTS
This thesis is the achievement of three years work, during which many people supported and
helped me. I would like to acknowledge all of them gratefully.
Special thanks to Alain Dassargues and Serge Brouyère who supervised this thesis. Thank you to
them for all advices and discussions we had together during these years. Thank you for the time
they spent to read this manuscript and give me some remarks and corrections. I also would like
to acknowledge them for their important support when I applied for a position of 'research
fellow' at FNRS, in 2006. I also remember the times we spent together in meetings and
conferences. These times were both very instructive and pleasant. Finally, I would like to thank
Alain Dassargues for proposing me to join his team and giving us the means to carry out research
in a pleasant work environment.
Thank you to Robert Charlier, Michel Pirotton, René Therrien, Stephen Blenkinsop and Marnik
Vanclooster, who have accepted to join the jury of this thesis and to take time to read this report.
I am very grateful to René Therrien, Daniela Blessent and Jean-Michel Lemieux for helping me to
use 'HydroGeoSphere'. Thank you for their precious advices and recommendations. Thank you
to René Therrien who allowed me to spend 3 months in his team at University Laval (Québec,
Canada). Thanks to him, his family and Daniela Blessent for their warm welcome in Québec.
Similarly, special thanks to Hayley Fowler, Stephen Blenkinsop and Aidan Burton for the work
we have performed together to generate climate change scenarios for the Geer basin. Thank you
to them, as well as Isabella and Micol for the time spent in Newcastle. Thank you to Mary Hill
for giving me the opportunity to teach a short course with her and for answering very quickly to
my e-mails and questions about 'UCODE_2005'.
Acknowledgements
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I am grateful to FNRS, which funded this research. FNRS and the University of Liège also
financed some presentations in international conferences, as well as scientific stays in University
Laval (Québec, Canada) and Newcastle University (Newcastle Upon Tyne, United Kingdom).
Thank you to the European Union FP6 Integrated Project AquaTerra (Project No. 505428),
which allowed me to meet very interesting people and to have decisive discussions.
Many thanks to the Administration of the Walloon Region, the 'Compagnie Intercommunale
Liégeoise des Eaux' (CILE), the 'Société Wallonne des Eaux' (SWDE), the 'Vlaamse Maatschappij
voor Watervoorziening (VMW), and the 'Afdeling Waterbouwkundig Laboratorium' of the
Flemish Region for all data they have provided about the Geer Basin.
Thank you to Christiane, Martine and Nadia, the secretariat staff, for their availability. Thank you
to Annick Anceau, from the 'Earth Science Library' of the University of Liège, for helping me in
bibliographic research. Thank you to the 'General IT department' (SEGI) of the University of
Liège, for their precious advices about 'NIC3', the super computer for intensive calculation at
University of Liège.
Particular thanks to all my colleagues and friends from the Hydrogeolgy Group and other teams:
Piotr, Philippe, Julie G., Ingrid, Samuel, Pierre J., Matthieu, Fabien, Julie C., Max, Pierre G.,
Nicolas, Cristina, Jordi, Laurent T., Jean -Michel, Tanguy, David, Jean, Frederic and many others.
Special thanks to Piotr who shared my office during more than 3 years.
Finally, I would like to address warm thanks to all my family. Particular thanks to you Céline for
your support and comprehension during these years. Thank you for your patience when I was
abroad. Thank you to have accompanied me in Quebec with the children. Thank you to be there
with me.
Pascal Goderniaux (January 2010)
Table of contents
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TABLE OF CONTENTS
Summary__________________________________________________________________ 5
Acknowledgements __________________________________________________________ 7
Table of contents ___________________________________________________________ 9
List of figures _____________________________________________________________ 12
List of tables ______________________________________________________________ 15
Knowledge dissemination____________________________________________________ 16
1. Introduction __________________________________________________________ 21
1.1 Introduction ___________________________________________________________ 23 1.2 References_____________________________________________________________ 26
2. Scientific review _______________________________________________________ 27
2.1 Introduction ___________________________________________________________ 29 2.2 Groundwater modelling _________________________________________________ 29 2.3 Climate change modelling ________________________________________________ 34
2.3.1 Global Circulation Models (GCM) _______________________________________________ 35 2.3.2 Climate downscaling__________________________________________________________ 36 2.3.3 Greenhouse gases emissions scenarios ____________________________________________ 40
2.4 Evaluation of the uncertainty linked to climate change impact__________________ 42 2.5 References_____________________________________________________________ 44
3. Methodology __________________________________________________________ 49
3.1 Methodology ___________________________________________________________ 51 3.2 References_____________________________________________________________ 55
4. The Geer basin ________________________________________________________ 57
4.1 Geographical and geological contexts ______________________________________ 59 4.2 Hydrogeological context _________________________________________________ 60 4.3 References_____________________________________________________________ 64
5. Modelling ____________________________________________________________ 65
5.1 Hydrological modelling __________________________________________________ 67 5.1.1 Conceptual model ____________________________________________________________ 67 5.1.2 Mathematical and numerical model ______________________________________________ 67 5.1.3 Discretisation________________________________________________________________ 71 5.1.4 Specified Fluxes _____________________________________________________________ 72 5.1.5 Calibration procedure _________________________________________________________ 73
5.1.5.1 Parameter values ________________________________________________________ 74 5.1.5.2 Evaluation of the calibration _______________________________________________ 78
Table of contents
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5.2 Sensitivity Analysis _____________________________________________________ 87 5.3 Discussion _____________________________________________________________ 91 5.4 Alternative calibration___________________________________________________ 94 5.5 References_____________________________________________________________ 97
6. Application of climate change scenarios on the Geer basin model _______________ 99
6.1 Climate scenarios ______________________________________________________ 101 6.2 Downscaling of RCM output_____________________________________________ 103 6.3 Projected changes in local climate ________________________________________ 104 6.4 Projected changes in hydrological regime __________________________________ 107 6.5 Discussion ____________________________________________________________ 110 6.6 References____________________________________________________________ 119
7. Application of stochastic climate change scenarios on the Geer basin model _____ 121
7.1 Objectives ____________________________________________________________ 123 7.2 Simulation of the stochastic climate change scenarios ________________________ 124
7.2.1 Generation of precipitations times series using 'RainSim'_____________________________ 125 7.2.1.1 General concepts _______________________________________________________ 126 7.2.1.2 Calibration of the model for the control scenarios (without any climate change) ______ 127 7.2.1.3 Calibration of the model for the climate change scenarios _______________________ 129 7.2.1.4 Generation of the climate change time series for the Geer basin___________________ 134
7.2.2 Generation of PET time series using the 'CRU daily weather generator' _________________ 134 7.2.2.1 General concepts _______________________________________________________ 135 7.2.2.2 Generation of the climate change time series for the Geer basin___________________ 136
7.3 Application of the climate change scenarios on the Geer basin model ___________ 138 7.3.1 Simulation conditions ________________________________________________________ 138 7.3.2 Evolution and uncertainty of projected groundwater levels and surface water flow rates ____ 138 7.3.3 Temporal uncertainty of a specific event _________________________________________ 145
7.4 Verification simulations of modelling hypotheses____________________________ 147 7.4.1 Influence of the number of equiprobable climatic scenarios___________________________ 147 7.4.2 Influence of the time discretisation ______________________________________________ 150
7.5 Discussion ____________________________________________________________ 153 7.6 References____________________________________________________________ 156
8. Uncertainty linked to the calibration of the model and summary of the results ____ 157
8.1 Introduction and objectives______________________________________________ 159 8.2 Estimation of the uncertainty linked to the calibration of the hydrological model _ 160
8.2.1 Methodology _______________________________________________________________ 161 8.2.2 Application of the methodology on the Geer basin hydrological model__________________ 165 8.2.3 Discussions about the confidence intervals________________________________________ 167
8.3 Summary of the results about climate change impact uncertainty ______________ 170
Table of contents
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8.3.1 Uncertainty linked to the natural variability of the climate____________________________ 170 8.3.2 Uncertainty linked to the climatic models_________________________________________ 171 8.3.3 Uncertainty linked to the downscaling technique ___________________________________ 171 8.3.4 Uncertainty linked to the calibration of the hydrological model________________________ 172
8.4 Conclusions about uncertainty ___________________________________________ 174 8.5 References____________________________________________________________ 177
9. Conclusions and perspectives ___________________________________________ 179
9.1 Conclusions___________________________________________________________ 181 9.1.1 Hydrological modelling_______________________________________________________ 181 9.1.2 Climate change scenarios _____________________________________________________ 182 9.1.3 Uncertainty evaluation _______________________________________________________ 183 9.1.4 Impact for the Geer basin _____________________________________________________ 184 9.1.5 General conclusion __________________________________________________________ 185
9.2 Perspectives __________________________________________________________ 185
Appendix ________________________________________________________________ 187
List of figures
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LIST OF FIGURES
Figure 2.1. (Figure and legend from IPCC, 2001b). The time evolution of the globally average
temperature change relative to the control run of the CMIP2 simulations. […].........................37 Figure 2.2. (Figure and legend from IPCC, 2000) Total global annual CO2 emissions from all sources
(energy, industry, and land-use change) from 1990 to 2100 (in gigatonnes of carbon
(GtC/yr)) for the families and six scenario groups. […] Each coloured emission band
shows the range of harmonized and non-harmonized scenarios within each group. For
each of the six scenario groups an illustrative scenario is provided (solid and dashed
lines). […] ................................................................................................................................................42 Figure 4.1. Location of the Geer basin and hydrologic limits..............................................................................59 Figure 4.2. Geological cross-section in the Hesbaye aquifer (modified from (modified from Brouyère
et al., 2004b)), with a vertical exaggeration equal to 40....................................................................60 Figure 4.3. Piezometry of the chalk aquifer (in metres above sea level) based on 2088 data (modified
from Orban, 2009; Ruthy, 2009). ........................................................................................................61 Figure 4.4. Evolution of groundwater levels at the observation well 'VIE044', from 1950 to 2006. ............63 Figure 5.1. Spatial discretisation of the Geer basin................................................................................................72 Figure 5.2. Distribution of the hydraulic conductivity zones for the chalk finite elements layers
(results of calibration)............................................................................................................................75 Figure 5.3. (A) Computed steady-state surface water elevations. (B) Computed steady-state subsurface
saturation, with full saturation shown in red (1967-1968)...............................................................79 Figure 5.4. Graphical analysis of the model calibration. (A) Computed values vs. observed values. (B)
Residuals vs. observed values. (C) Weighted residuals vs. observed values. Doted lines
represent increments of the calculated standard error. ....................................................................80 Figure 5.5 : Transient calibration of hydraulic heads for the nine observation wells.......................................85 Figure 5.6. Transient calibration of surface flow rates for the Kanne gauging station (outlet) ......................86 Figure 5.7. Composite Scales Sensitivities (CSS) of the parameters used in the Geer basin model ..............89 Figure 5.8. (A) Aggregated sensitivities for each observation point. (B) Mean leverage statistics for
each observation point. .........................................................................................................................91 Figure 5.9. Transient calibration of hydraulic heads for the 8 observation wells (2nd model).......................95 Figure 5.10. Transient calibration of surface flow rates for the Kanne gauging station (2nd model) ...........95 Figure 5.11. Graphical analysis of the model calibration. (A) Computed values vs. observed values.
(B) Residuals vs. observed values. (C) Weighted residuals vs. observed values...........................96 Figure 6.1. Monthly climatic changes for each climate change scenario (period 2071-2100) relatively to
1961-1990. (A) Temperature - Bierset climatic station. (B) Precipitation - Waremme
climatic station. .................................................................................................................................... 105
List of figures
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Figure 6.2. Monthly climatic changes for the three time period 2011-2040, 2041-2070, 2071-2100
(climate model RCAO_E) relatively to 1961-1990. (A) Temperature – Bierset climatic
station. (B) Precipitation – Waremme climatic station.................................................................. 106 Figure 6.3. Evolution of hydraulic heads at the eight observation wells for each climate change
scenario, using the model with calibration 1................................................................................... 111 Figure 6.4. Evolution of hydraulic heads at the eight observation wells for each climate change
scenario, using the model with calibration 2................................................................................... 112 Figure 6.5. Evolution of flow rates at gauging station 'Kanne' for each climate change scenario, using
the model with calibration 1.............................................................................................................. 113 Figure 6.6. Evolution of flow rates at gauging station 'Kanne' for each climate change scenario, using
the model with calibration 2.............................................................................................................. 113 Figure 7.1. Schematic of the NSRP stochastic rainfall model (Figure from Burton et al., 2008). The
circles represent the rainfall events. Each star is associated with the beginning of a 'rain
cell'. ........................................................................................................................................................ 126 Figure 7.2. Observed, fitted and simulated precipitation statistics for the Geer basin climate
corresponding to the period 1961 – 1990 ....................................................................................... 129 Figure 7.3. Evolution of the scaling factors between 1975 and 2085 for GCM ECHAM4/OPYCA2..... 131 Figure 7.4. Target climatic statistics of RCAO_E for years 1995, 2025, 2055, 2085 .................................... 132 Figure 7.5. Evolution of target and mean simulated statistics (for successive periods of 1000 years)
between 1975 and 2085 for RCAO_E ............................................................................................ 133 Figure 7.6. Stochastic climate change scenarios. Precipitations of RCAO_E and ARPEGE_H for
February and August .......................................................................................................................... 134 Figure 7.7. Stochastic climate change scenarios. Monthly mean temperature of RCAO_E and
ARPEGE_H for February and August........................................................................................... 137 Figure 7.8. Stochastic climate change scenarios. Monthly mean PET of RCAO_E and ARPEGE_H
for February and August.................................................................................................................... 137 Figure 7.9. Evolution of hydraulic heads at the 8 observation wells for 30 equiprobable climatic
scenarios of ARPEGE_H (2010 – 2085)........................................................................................ 140 Figure 7.10. Evolution of hydraulic heads at the 8 observation wells for 30 equiprobable climatic
scenarios of RCAO_E (2010 - 2085)............................................................................................... 141 Figure 7.11. Mean hydraulic heads at the 8 observation wells for each of the 6 climatic models (30
scenarios) .............................................................................................................................................. 142 Figure 7.12. Evolution of water flow rate at the outlet of the basin for 30 equiprobable climatic
scenarios of ARPEGE_H and RCAO_E (2010 - 2085) .............................................................. 143 Figure 7.13. Mean water flow rate at the outlet of the basin for each of the 6 climatic models (30
scenarios) .............................................................................................................................................. 143
List of figures
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Figure 7.14. (A) Mean groundwater levels (30 scenarios) and 95% interval at observation point
'OTH002', (B) mean annual water flow rates (30 scenarios) and 95% interval at
'KANNE', for the control simulations and the climatic models ARPEGE_H and
RCAO_E. ............................................................................................................................................. 145 Figure 7.15. Number of outcomes (10 m decrease in OTH002 groundwater level) for each time
interval and each climatic model....................................................................................................... 147 Figure 7.16. Probability density function and 95% interval for HIRHAM_H (OTH002)........................... 147 Figure 7.17. Results comparison when using 30 or 100 equiprobable scenarios of the climatic model
ARPEGE_H. (A) Mean groundwater levels and 95% interval at observation point
'OTH002'. (B) Mean annual water flow rates and 95% interval at 'KANNE'. ......................... 149 Figure 7.18. Comparisons of probability density functions and 95% intervals for ARPEGE_H
(OTH002) using 30 and 100 equiprobable scenarios. The vertical dotted lines represent
the limits of the 95% interval. ........................................................................................................... 149 Figure 7.19. Results comparison when using daily or monthly input solicitations for 30 equiprobable
scenarios of the climatic model ARPEGE_H. (A) Mean groundwater levels and 95%
interval at observation point 'OTH002'. (B) Mean monthly water flow rates and 95%
interval at 'KANNE' (February). (C) Mean monthly water flow rates and 95% interval at
'KANNE' (August). ............................................................................................................................ 152 Figure 8.1. Predictions and 95 % confidence interval around predicted values for 8 years of a
HIRHAM_H downscaled climate change scenario. (A) Absolute groundwater levels. (B)
Groundwater levels change between a scenario without any climate change and the
HIRHAM_H climate change scenario. ........................................................................................... 169 Figure 8.2. Predictions and 95 % confidence interval around predicted values for 8 years of a
HIRHAM_H downscaled climate change scenario. (A) Absolute surface water monthly
flow rates. (B) Change in surface water monthly flow rates between a scenario without
any climate change and the HIRHAM_H climate change scenario. .......................................... 170 Figure 8.3. Summary of all results and uncertainties for the 8 groundwater observation points. The
horizontal red line represents the 'control' mean groundwater level without any climate
change. .................................................................................................................................................. 173 Figure 8.4. Summary of all results and uncertainties for the water flow rate at the outlet of the
catchment ('Kanne'). The horizontal line represents the 'control' mean flow rate without
any climate change. ............................................................................................................................. 174
List of tables
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LIST OF TABLES
Table 2.1. Selected examples of AOGCMs and spatial resolution (IPCC, 2001b; IPCC, 2007b)..................36 Table 2.2. SRES emissions scenarios (IPCC, 2000)...............................................................................................41 Table 5.1. Parameters used in the flow model........................................................................................................68 Table 5.2. Van Genuchten parameters, total porosity and specific storage.......................................................74 Table 5.3. Full saturated hydraulic conductivities values of the calibrated zones (results of calibration).....75 Table 5.4. Values for the Manning roughness coefficients and coupling length ..............................................76 Table 5.5. Root depths, evaporation depths and Leaf Area Index......................................................................77 Table 5.6. Mean errors between observed and computed heads for the nine observation wells (hobs:
observed hydraulic head, hcomp: computed hydraulic head, N: number of observations). .........82 Table 5.7. Simulated mean water balance terms for the period 1967-2003 .......................................................87 Table 6.1. Climate change scenarios with corresponding RCM and GCM. DMI: Danish
Meteorological Institute, HC: Hadley Center for Climate Prediction and Research, SMHI:
Swedish Meteorological and Hydrological Institute. ..................................................................... 102 Table 6.2. Variations of the mean water balance terms for each climate change scenario and time
interval, using the model with calibration 1. ................................................................................... 114 Table 6.3. Variations of the mean water balance terms for each climate change scenario and time
interval, using the model with calibration 2. ................................................................................... 115 Table 7.1. Random variables used in the NSRP model ..................................................................................... 127 Table 8.1. Summary of the results about climate change impact uncertainty for the period 2071-2100
(calculated with the first hydrological model, calibrated with daily stresses)............................. 170 Table A2. Van Genuchten parameters, total porosity and specific storage.................................................... 189 Table A3. Full saturated hydraulic conductivities values of the calibrated zones (results of calibration) .. 189 Table A4. Values for the Manning roughness coefficients and coupling length ........................................... 189 Table A5. Root depths, evaporation depths and Leaf Area Index................................................................... 190 Table A6. Simulated mean water balance terms for the period 1967-2003 .................................................... 190
Knowledge dissemination
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KNOWLEDGE DISSEMINATION
Journal articles
- Goderniaux P., Brouyère S., Fowler H.J., Blenkinsop S., Therrien R., Orban Ph., Dassargues
A., 2009. Large scale surface - subsurface hydrological model to assess climate change impacts
on groundwater reserves. Journal of Hydrology, 373, 1-2, 122-138 pp.
- Barth J.A.C., Kalbus E. , Schmidt C. , Bayer-Raich M., Reinstorf F., Schirmer M., Thiéry D.,
Dubus I.G., Gutierrez A., Baran N., Mouvet C., Petelet-Giraud E., Négrel Ph., Banton O.,
Batlle Aguilar J., Brouyère S., Goderniaux P., Orban Ph, Rozemeijer J.C., Visser A., Bierkens
M.F.P., Van der Grift B., Broers H.P., Marsman A., Klaver G., Slobodnik J., Grathwohl P.,
2007. Selected groundwater studies of EU project AquaTerra leading to large-scale basin
considerations. Water Practice & Technology, 2-3, 10 pp.
- Visser A., Dubus I., Broers H.P., Brouyère S., Korcz M., Orban Ph., Goderniaux P., Batlle-
Aguilar J., Surdyk N., Amraoui N., Job H., Pinault J.-L., Bierkens M., 2009. Comparison of
methods for the detection and extrapolation of trends in groundwater quality. Journal of
Environmental Monitoring, 11, 2030-2043 pp.
- Goderniaux et al., 2010. Climate change impact on groundwater reserves using stochastic
climatic scenarios. Manuscript in preparation.
- Orban Ph., Brouyère S., Couturier J., Goderniaux P., Batlle-Aguilar J., Dassargues A., 2010.
Modelling nitrate trends a in chalk aquifer at regional scale. Manuscript in preparation.
- Blenkinsop S., Fowler H.J., Harpham C., Burton A., Goderniaux P., 2010. Modelling
transient climate change with a stochastic weather generator: Projected temperature changes
for the Geer catchment, Belgium. Manuscript in preparation.
Knowledge dissemination
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Conference proceedings
- Goderniaux P., Brouyère S., Fowler H.J., Blenkinsop S., Therrien R., Orban Ph., Dassargues
A., 2009. How can large scale surface - subsurface hydrological model be used to evaluate long
term climate change impacts on groundwater reserves. The 7th International Conference on
Calibration and Reliability in Groundwater Modeling. "Managing Groundwater and the
Environment". Proceedings of MODELCARE 2009. Wuhan, China, September 2009, 137-
140 pp.
- Goderniaux P., Brouyère S., Dassargues A., 2007. Integrated approach for assessing climate
change impacts on a regional chalky aquifer in Belgium. Changes in Water Resources Systems:
Methodologies to Maintain Water Security and Ensure Integrated Management. Proceedings
of Symposium HS3006 at IUGG 2007, Perugia (Italy), July 2007, Vol. 315, 100-105 pp.
Conference abstracts
- Goderniaux P., Brouyère S., Fowler H.J., Blenkinsop S., Therrien R., Orban Ph., Dassargues
A., 2009. Large Scale Integrated Surface - Subsurface Hydrological Model to Assess Climate
Change Impacts on Groundwater Resources. The 2009 Ground Water Summit - The Science
and Engineering Conference: Adapting to Increasing Demands in a Changing Climate.
National Ground Water Association. Tucson, USA, April 2009.
- Orban Ph., Brouyère S., Couturier J., Wildemeersch S., Goderniaux P., Batlle-Aguilar J.,
Dassargues A., 2009. Assessment of Nitrate Trends in Groundwater Using the Regional Scale
HFEMC Approach. The 2009 Ground Water Summit - The Science and Engineering
Conference: Adapting to Increasing Demands in a Changing Climate. National Ground Water
Association. Tucson, USA, April 2009.
- Orban Ph., Goderniaux P., Batlle-Aguilar J., Brouyère S., 2009. Large-scale flow and
transport modelling for the management of groundwater bodies. AquaTerra Final Conference.
Processes-Data-Models-Future Scenarios. Scientific Fundamental for River Basin
Management. Tubingen, Germany, March 2009.
- Blenkinsop S., Fowler H.J., Burton A., Bovolo I., Van Vliet M., Goderniaux P., Forlin L.,
Harpham C., 2009. State-of-the-art climate change scenarios in AquaTerra. AquaTerra Final
Knowledge dissemination
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Conference. Processes-Data-Models-Future Scenarios. Scientific Fundamental for River Basin
Management Tubingen, Germany, March 2009.
Scientific report – AquaTerra Project
- Goderniaux P., Brouyère S., Orban Ph., Dassargues A., Fowler H.J., Blenkinsop S., 2009.
Report on the development of the Geer hydrological model. Final results about climate
change impacts evaluation. Deliverable R3.30, AquaTerra (Integrated Project FP6 no. 505428),
60 pp.
- Goderniaux P., Brouyère S., Orban Ph., Dassargues A., 2008. Development of the Geer
basin hydrological model for climatic scenarios and first results about impacts evaluation.
Deliverable R3.26, AquaTerra (Integrated Project FP6 no. 505428), 29 pp.
- Goderniaux P., Brouyère S., Orban Ph., Dassargues A., 2007. Intermediate report on the
development of the Geer hydrological model (surface and subsurface water) for climatic
change scenario on that subcatchment. Deliverable R3.21, AquaTerra (Integrated Project FP6
no. 505428), 17 pp.
- Broers H.P., Visser A., Bierkens M., Dubus I., Pinault J.L., Surdyk N., Guyonnet D., Batlle-
Aguilar J., Brouyère S., Goderniaux P., Orban Ph., Korcz M., Bronder J., Dlugosz J.,
Odrzywolek M., 2008. Draft overview paper on trend analysis in groundwater summarizing
the main results of TREND2 in relation to the new Groundwater Directive. Deliverable
T2.12, AquaTerra (Integrated Project FP6 no. 505428), 46 pp.
- Dubus, I., Pinault J.-L., Surdyk N., Guyonnet D., Broers H.P., Visser A., Orban Ph., Batlle-
Aguilar J., Goderniaux P., Brouyère S., 2008. Report with comparison of statistical and
physically deterministic methods of trend assessment and extrapolation in terms of data
requirements, costs and accuracy. Deliverable T2.11, AquaTerra (Integrated Project FP6 no.
505428), 33 pp.
- Broers H.P., Visser A., Heerdink R., Van der Grift B., Surdyk N., Dubus I., Amaoui N.,
Orban Ph., Batlle-Aguilar J., Goderniaux P., Brouyère S., 2008. Report which describes the
physically deterministic determination and extrapolation of time trends at selected test
locations in Dutch part of the Meuse Basin, the Brévilles catchment and the Geer catchment.
Deliverable T2.10, AquaTerra (Integrated Project FP6 no. 505428), 47 pp.
Knowledge dissemination
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- Hérivaux, C., Orban Ph., Batlle-Aguilar J., Brouyère S., Goderniaux P., 2008. Socio-economic
analysis integrating soil-water system modelling for the Geer catchment (Meuse, Walloon
region) - diffuse nitrate pollution in groundwater. Deliverable I3.8, AquaTerra (Integrated
Project FP6 no. 505428), 45 pp.
- Orban, Ph., Batlle-Aguilar J., Goderniaux P., Dassargues A., Brouyère S., 2006. Description
of hydrogeological conditions in the Geer sub-catchment and synthesis of available data for
groundwater modelling. Deliverable R3.16, AquaTerra (Integrated Project FP6 no
505428), 20 pp.
Additional publications
- Brouyère S., Batlle-Aguilar J., Goderniaux P., Dassargues A., 2008. A New Tracer Technique
for Monitoring Groundwater Fluxes: The Finite Volume Point Dilution Method. Journal of
Contaminan Hydrology, 95, 3-4, 121-140 pp.
- Goderniaux P., Brouyère S., Gutierrez A., Baran N., 2010. Persistence of agricultural
groundwater contamination related to hydraulic stratification as shown by long-term tracer
tests. Submitted to Hydrogeology Journal. Under revision.
- Brouyère S., Batlle-Aguilar J., Goderniaux P., Dassargues A., 2007. A new single well tracer
test: The Finite Volume Point Dilution Method. Theory, field application and model
validation – in "Calibration and Reliability in Groundwater Modelling – Credibility in
Modelling – Pre-published proceedings of MODELCARE 2007. Copenhagen, Danemark, 67-
92 pp.
Knowledge dissemination
20
1. Introduction
21
1. INTRODUCTION
1. Introduction
22
1. Introduction
23
1.1 Introduction
According to the Fourth Assessment Report (AR4) of the Intergovernmental Panel on Climate
Change (IPCC, 2007a), "Warming of the climate system is unequivocal, as is now evident from
observations of increases in global average air and ocean temperatures, widespread melting of
snow and ice and rising global average sea level". This report also concludes with 'very high
confidence' that this global warming was mostly due to the effect of human activities through
emissions of greenhouse gases in the atmosphere. For more than one decade, issues linked to
climate change have actually raised in importance in societies and political circles. Though
international agreements are difficult to achieve, more and more nations have the reduction of
greenhouse gases emissions in their agenda. In 1997, several countries adopted the 'Kyoto
Protocol' which agrees on an average 5% reduction compared to 1990 emissions over the period
2008-2012 (UNFCCC, 2009). In 2009, the recent 'Copenhagen Accord' "[…] recognises the
scientific view that the increase in global temperature should be maintained below 2 degrees
Celsius […]" to stabilise greenhouse gas concentration in the atmosphere at a level that would
prevent dangerous anthropogenic interference with the climate system (UNFCCC, 2009). Climate
change is likely to bring harmful effects on many ecosystems and human life and activities. Rising
sea levels may submerge inhabited areas, inducing massive migration of population. The
progression of deserts or more frequent occurrences of violent and destructive climatic events
could make life very difficult in some areas, constraining people to adapt themselves to new
conditions. One of the most important indirect issues linked to climate change relates to water
supply, which is obviously essential for life. The availability of water is also necessary for almost
any human activities, including agriculture and associated food security issues. A lot of scientific
research about impact estimation has been carried out in this particular topic. Nevertheless, this
research is often restricted to surface water reserves, neglecting groundwater. However,
groundwater represents an important percentage of total water supply across the world.
1. Introduction
24
According to the United Nations Environment Program about groundwater (UNEP - Morris et
al., 2003), "the contribution from groundwater is vital". Perhaps as many as two billion people
depend directly upon aquifers for drinking water. Forty percent of the world's food is produced
by irrigated agriculture that relies largely on groundwater and over half of the largest megacities in
the world directly rely on local groundwater or make significant use of it. Groundwater often
constitutes the only available resource in arid zones, but is also largely used under more
temperate climates, like in Walloon Region, where approximately 80% of the water supply comes
from aquifers (DGARNE, 2009). Groundwater reserves will continue to be heavily used in the
future, because they constitute an important part of available freshwater in our planet, but also
because groundwater is less sensitive to sudden climatic variations, compared to surface water. In
2001, IPCC experts also reported that "Groundwater is the major source of water across the
world", but they also noticed that "There has been very little research on the potential effects of
climate change" (IPCC, 2001a). Considering this gap, the International Association of
Hydrogeologists (IAH) has created in 2004 a new commission on this particular topic to support
research, studies and international contacts. Though more research has been carried out since the
report of 2001, the lack of knowledge about groundwater and groundwater – surface water
interactions is repeated in the IPCC technical paper about "Climate Change and Water" in 2008
(Bates et al., 2008). Moreover, the few scientific works about climate change impact on
groundwater show variable results. Though differences in the studied climate and aquifer types
surely exert an influence, the way of representing climatic and hydrogeologic systems certainly
contributes to variability in results and uncertainty. Additionally, the uncertainty linked to climate
change impact is not evaluated, or from a very limited number possible uncertainty sources. The
evaluation of this uncertainty is however of major importance to give some credibility to the
climate change impact study. It also enables water managers to analyse risks and take decisions
with full knowledge of projected impact and their degree of confidence.
1. Introduction
25
Considering this general context, the general objectives of this research are the following:
(1) development of a methodology for a reliable estimation of the climate change impacts on
groundwater reserves;
(2) estimation of the uncertainties characterising these projected impacts, considering various
possible uncertainty sources;
(3) pilot application of the two first objectives on the case of the Geer basin catchment
(Belgium).
In Section 2 of this thesis, a review of the scientific studies performed in the field of groundwater
and climate change is performed. In response to the relative weaknesses and strengths identified
in this existing scientific literature, Section 3 presents the methodology developed and used in the
current research. Section 4 describes the geological and hydrological contexts of the Geer basin.
Sections 5 to 8 expose the work performed and the main outcomes of the research, as obtained
following the methodology described in Section 3 ('Methodology'). Finally, Section 9 provides
conclusions and a reflection relative to the research perspectives.
1. Introduction
26
1.2 References
Bates, B.C., Kundzewicz, Z.W., Wu, S. and Palutikof, J., 2008. Climate Change and Water. Technical Paper of the Intergovernmental Panel on Climate Change, IPCC Secretariat, Geneva.
DGARNE, 2009. Etat des nappes d'eau souterraine de la Wallonie. Huitième année. Décembre 2009., Service Public de Wallonie. Direction générale opérationnelle, Agriculture, Ressources naturelles et Environnement. Direction de l'état environnemental. Direction des eaux souterraines.
IPCC (Editor), 2001. Climate Change 2001: Impacts, Adaptation and Vulnerability, Contribution of the working group II to the third assessment report of the Intergovernmental Panel on Climate Change (IPCC). Cambridge Univ. Press (UK), 1000 pp.
IPCC, 2007. Climate Change 2007: Synthesis Report. Contribution of Working Groups I, II and III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, IPCC, Geneva, Switzerland.
Morris, B.L., Lawrence, A.R.L., Chilton, P.J.C., Adams, B., Calow, R.C. and Klinck, B.A., 2003. Groundwater and its Susceptibility to Degradation: A Global Assessment of the Problem and Options for Management. Early Warning and Assessment Report Series, RS. 03-3. United Nations Environment Programme, Nairoby, Kenya, 138 pp.
UNFCCC, 2009. http://unfccc.int - Official website of the United Nations Framework Convention on Climate Change (UNFCCC).
2. Scientific review
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2. SCIENTIFIC REVIEW
2. Scientific review
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2. Scientific review
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2.1 Introduction
A huge number of research studies have been performed about climate change, through various
subjects such as the causes, modelling or impact of climate change on many types of systems.
The scientific review that follows this short introduction does not aimed to provide an inventory
of all of them, but focuses on climate change impact studies performed in the field of
groundwater, and on tools and methods used to achieve them. Particularly, it focuses on the
groundwater modelling work performed in the context of climate change. It also presents the
different modelling approaches to generate climate change scenarios and how they have been
used in groundwater impact studies. Finally, issues relative to uncertainty evaluation are briefly
discussed. This review attempts to highlight the weaknesses and strengths of previous studies,
and constitutes a foreword to the research performed in the framework of this thesis.
2.2 Groundwater modelling
Estimating the possible impacts of climate change on water resources represents one of the most
difficult challenges faced by water managers. Because of the great interest in such projections,
several studies have been recently published on the topic (see for example Christensen et al.,
2004; Fowler et al., 2003; Fowler et al., 2007b; Gellens and Roulin, 1998; VanRheenen et al.,
2004; Wilby et al., 2006). As already mentioned in Section 1, most of these studies focus on
surface water and generally oversimplify or even neglect groundwater, although groundwater is
the main water supply in many parts of the world. Additionally, studies that try to assess climate
change impact on water resources are likely to produce variable results (Jiang et al., 2007). One of
the main reasons for the discrepancy in projections is that simplistic assumptions are often made
to represent the physical processes associated with hydrological systems. This is particularly the
case for the studies that account for groundwater, where the representation of processes
2. Scientific review
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associated with subsurface flows and groundwater recharge brings additional complexity. These
assumptions increase the uncertainty associated with model projections and need to be addressed.
A first requirement for estimating the impact of climate change on groundwater systems is a
reliable estimate of the volume of water entering and leaving an aquifer. More specifically, a
reliable estimate of groundwater recharge is needed because it represents the connection between
atmospheric and surface-subsurface processes and is therefore a key element in the context of the
impacts of climate change on groundwater. Similarly, in aquifers strongly influenced by surface
water, groundwater discharge into rivers may be affected by changes in surface water levels, and
consequently affect groundwater levels (Scibek et al., 2007). In previous studies about climate
change impact on groundwater reserves (see for example Brouyère et al., 2004b; Chen et al.,
2002; Holman, 2006; Loáiciga, 2003; Scibek et al., 2007; Serrat-Capdevila et al., 2007;
Woldeamlak et al., 2007), recharge has been estimated with various degrees of complexity,
ranging from simple linear functions of precipitation and temperature (Chen et al., 2002; Serrat-
Capdevila et al., 2007) to the application of "soil models" simulating variably-saturated
groundwater flow and solute transport (Allen et al., 2004; Brouyère et al., 2004b; Scibek and
Allen, 2006b).
Chen et al. (2002) and Chen et al. (2004) developed an empirical model, linking groundwater
levels to climatic variables, for a carbonate rock aquifer in Manitoba (Canada), and proposed to
use it for predicting groundwater levels under climate change conditions. Within this empirical
model, recharge is linked to precipitation and temperature using simple water balance linear
functions.
Serrat-Capdevilla et al. (2007) evaluate climate change impact on groundwater in the San Pedro
basin (Arizona, USA) for the period from 2000 to 2100, using a three dimensional 'MODFLOW'
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model (Harbaugh, 2005). They calculate the 'mountain-front' recharge into the riparian basin
using an empirical relationship linking recharge to precipitation.
Loaiciga et al. (2000) and Loaiciga (2003) use the 'GWSIM' (Ground Water Simulation Program)
two-dimensional finite-difference model to study the impact of climate change on the Edwards
regional karst aquifer (Texas, USA), under various pumping conditions. Recharge is estimated
from a water balance of the streamflow in the area.
Allen et al. (2004), Scibek and Allen (2006b), Scibek and Allen (2006a), Scibek et al. (2007) study
climate change impact on the 'Grand Forks' Aquifer (British Columbia, Canada) which is an
alluvial aquifer strongly influence by river stages. They use a three dimensional 'MODFLOW'
groundwater model, together with the more complex 'HELP' model (Hydrologic Evaluation of
Landfill Performance – U.S. Environmental Protection Agency) (Schroeder et al., 1994) for
recharge rates calculation, and the 'BRANCH' model (Schaffranek et al., 1981) for river stages
calculation. The physically-based 'HELP' model enables to spatially calculate recharge rates taking
into account processes such as runoff, infiltration, evapotranspiration, surface and moisture
storage, snowmelt, etc.
Brouyère et al. (2004b) modelled groundwater flows under climate change conditions in a chalk
aquifer in Belgium. The saturated groundwater flow model is implemented with the finite
element code 'SUFT3D' (Brouyère, 2001; Carabin and Dassargues, 1999). Recharge rates are
calculated with the soil model 'EPIC-GRID', which performs water budget at the ground surface
level and in the unsaturated zone. Exchange fluxes are unidirectional, from the soil model to the
groundwater model.
Woldeamlak et al. (2007) and Yusoff et al. (2002) performed similar studies for a part of the
Grote-Nete basin (Belgium) and a chalk aquifer (West Norfolk, UK), respectively. In both
studies, the authors developed a groundwater model using 'MODFLOW'. Woldeamlak et al.
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(2007) calculate groundwater recharge rates with 'WetSpass' (Batelaan and De Smedt, 2001), a
spatially-distributed water balance model. Yusoff et al. (2002) use a more conventional soil water
balance method. Finally, other authors also studied the impact of climate change on groundwater
recharge without assessing the effect on groundwater reserves (see for example Eckhardt and
Ulbrich, 2003; Herrera-Pantoja and Hiscock, 2008; Holman, 2006; Holman et al., 2009; Jyrkama
and Sykes, 2007).
Though groundwater recharge rates were estimated with various degrees of complexity in
previous studies and models, none of them can simulate the feedback, or fluid exchange, between
the surface and subsurface domains. This feedback is an integral component of the water cycle
since groundwater recharge depends on precipitation and evapotranspiration at the surface
domain, evapotranspiration in the vadose zone, evapotranspiration in the saturated zone when
water levels are close to the ground surface, and finally river – aquifer interactions. The
quantitative estimation of the latter four fluxes depends on the simulation of simultaneous
hydraulic conditions in the surface and subsurface domains. Therefore, estimating recharge by
only considering one part of the whole system is unrealistic, inaccurate and potentially unusable
in the context of climate change impact assessments. Similarly, loosely coupled modelling
approaches, where water exchange between surface and subsurface is calculated independently,
do not provide a sufficient level of realism because they do not solve for all the interdependent
processes simultaneously.
To compensate for this lack of interconnection when modelling groundwater, Van Roosmalen et
al. (2007) and Van Roosmalen et al. (2009) used a coupled model that simulates surface water and
groundwater flows simultaneously with water exchanges between both domains. This model,
described by Henriksen et al. (2003) and Sonneborg et al. (2003), and based on the 'MIKE SHE'
code (Graham and Butts, 2006; Refsgaard and Storm, 1995), is used to assess the impact of
climate and land use change on a large scale catchment in Denmark. However, this model uses a
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relatively simple water balance method (Yan and Smith, 1994) to compute water flows in the
partially saturated zone. While this kind of simplification could be used in area where the
influence of the partially saturated zone is limited (provided some verifications), it constitutes a
serious limitation in other cases. The development and use of physically-based, fully-integrated
hydrological models able to simulate surface- and subsurface-flow in the saturated and partially
saturated zones, with a simultaneous solution of the flow equations in all domains, have recently
gained attention. Currently, the few modelling codes that are able to simulate these processes in
an integrated way include 'HydroGeoSphere' (Therrien et al., 2005), the 'Integrated Hydrology
Model' (InHM) (VanderKwaak, 1999), 'ParFlow' (Kollet and Maxwell, 2006), and 'OpenGeoSys'
(Delfs et al., 2009). As an example of application, Jones (2005) developed such a model for a 75
km² catchment (Laurel Creek Watershed – Ontario, Canada) using 'InHM'. The finite element
grid representing the catchment contained more than 600 000 nodes and transient simulations of
coupled surface and subsurface flow were run over periods of 1 month with specified fluxes
input on an hourly basis. Sudicky et al. (2008) present a similar model for a 17 km² subcatchment
of the Laurel Creek Watershed and use it to simulate contaminant transport issues. Another
example is reported by Li et al. (2008), who modelled, using HydroGeoSphere, surface and
subsurface flows, and evapotranspiration fluxes for a 286 km² catchment (Duffins Creek
Watershed – Ontario, Canada) with more than 700 000 nodes and made transient simulations
over 1 year periods with specified fluxes input on a daily basis. Finally, Kollet & Maxwell (2008)
used 'ParFlow' to implement an integrated surface – subsurface model for the Little Washita
watershed (Oklahoma, United States), which area is approximately 600 km², and performed 1-
year transient simulations with hourly time steps. A drawback of these models is that fully-
integrated simulations typically require substantial computer resources, and most simulations
published have been either limited to small catchments or short time periods. As an example, the
model of Jones et al. (2005) takes more than 4 days of computational time to simulate a period of
1 month with a 3.2 GHz Pentium4 desktop machine equipped with 4.0 Gb RAM. To our
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knowledge, there is no example of such integrated surface – subsurface models used in the
context of climate change impact evaluation, which requires to simulate longer time periods
(typically 30 years minimum).
A second requirement for estimating the impact of climate change on groundwater systems is
that hydrogeological system models must be capable of consistently representing observed
phenomena, which is not always the case. As already presented above, Chen et al. (2002) propose
to estimate the impact of climate change on a Canadian aquifer with an empirical model that links
piezometric variations and groundwater recharge, where recharge is assumed to be a linear
function of precipitation and temperature. Most studies focussing on surface water, such as
Arnell (2003), also use simplistic transfer functions to represent exchanges between ground- and
surface water. However, such transfer functions often oversimplify the exchange processes.
These functions can still be substituted for more detailed physical representations for specific
conditions if they are verified with calibration, but their use may become uncertain if applied
stresses go beyond the calibration conditions, which is typical for climate change scenarios.
Detailed physically-based and spatially-distributed models that take into account hydrogeologic
processes provide more realistic simulations of groundwater fluxes, including exchanges with
surface water.
2.3 Climate change modelling
In addition to the choice of the hydrological modelling approach, the need for climate change
scenarios, to be used as input of hydrological models, add an additional layer of complexity and
uncertainty to future projections. Before proceeding to any hydrological simulations to evaluate
potential impacts, climatic stresses are needed and specific scenarios have primarily to be
produced.
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2.3.1 Global Circulation Models (GCM)
General Circulation Models (GCM) constitute an important tool to simulate climatic variables.
According to Grotch and MacCracken (1991), General Circulation Models are "numerical models
that attempt to simulate the global climate by calculating the evolution of the atmosphere in all
three spatial dimensions based on the conservation laws for atmospheric mass, momentum, total
energy, and water vapour". GCMs are actually complex numerical climate models based on
physical laws and implemented at the scale of the earth globe. A GCM is generally the
combination of an 'Atmospheric General Circulation Model' (AGCM) and an 'Oceanic
Circulation Model' (OGCM) to form an 'Atmosphere-Ocean General Circulation Model'
(AOGCM). According to their complexity and continuous developments, AOGCMs are also
coupled with other models such as sea-ice models, land surface processes, biosphere processes,
carbon cycle models, atmospheric chemistry, etc. (IPCC, 2001b; IPCC, 2007b). Numerous GCMs
are available and have been developed during the last decade. Some of them are shown in Table
2.1 along with specific characteristics such as spatial resolution. GCMs can then be used to
generate climate change scenarios by increasing, for example, the emissions of CO2 or other
greenhouse gases. As an illustration, Figure 2.1 (IPCC, 2001b) shows the evolution of simulated
global temperature using different GCMs and considering a CO2 increase of 1% per year.
However, a drawback linked to the use of GCMs is that they are very computationally expensive.
Additionally, GCMs simulate climatic variables at a very large scale, typically for spatial
resolutions between 2° and 5° of latitude and longitude. Hydrological or hydrogeological studies
are on the other hand performed at a much more local scale, typically from a few hundred
squared metres to several squared kilometres. GCMs are unable to accurately simulate climatic
variables for this smaller scale because they do not account for local effects such as topography,
hydrography, land use, etc. As a result, a comparison between climatic observations at a specific
measurement station and the climatic outputs from a particular GCM would probably lead to
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significant differences. Considering these issues, and particularly the mismatch of scales between
the spatial resolution of GCM outputs and the need for more local hydrological impact studies,
additional work is needed to produce appropriate climatic models and scenarios in this context.
Numerous techniques have been developed for years and are known as 'downscaling' techniques.
All existing techniques have been reviewed in several scientific papers, including Fowler et al.
(2007a) and Wilby and Wigley (1997). A very brief overview of these techniques, based on these
review papers is presented here after.
AOGCM Institute Resolution (atmosph.)
Resolution (ocean)
References
CCSM3 National Centre for Atmospheric Reasearch, USA
1.4° × 1.4° 1.0° × 1.0° (Collins et al., 2004)
CGCM3.1 Canadian Centre for Climate Modelling and Analysis, Canada
1.9° × 1.9° 10.9° × 1.4° (McFarlane et al., 1992)
CNRM-CM3 Météo-France, France 1.9° × 1.9° 2.0° × 2.0° (Deque et al., 1994)
ECHAM4/OPYC3
Max Planck Institute for Meteorology, Germany
2.8° × 2.8° 2.8° × 2.8° (Roeckner et al., 1996)
ECHAM5/MPI-OM
Max Planck Institute for Meteorology, Germany
1.9° × 1.9° 1.5° × 1.5° (Roeckner et al., 2003)
UKMO-HadCM3
Hadley Centre for Climate Prediction and Research/MET Office, UK
2.5° × 3.75° 1.25° × 1.25° (Gordon et al., 2000; Pope et al., 2000)
UKMO-HadGEM1
Hadley Centre for Climate Prediction and Research/MET Office, UK
1.3° × 1.9° 1.0° × 1.0° (Martin et al., 2004)
Table 2.1. Selected examples of AOGCMs and spatial resolution (IPCC, 2001b; IPCC, 2007b).
2.3.2 Climate downscaling
Downscaling techniques can be classified into two main categories: 'dynamical downscaling' and
'statistical downscaling'.
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Figure 2.1. (Figure and legend from IPCC, 2001b). The time evolution of the globally average temperature
change relative to the control run of the CMIP2 simulations. […]
'Dynamical downscaling' mainly relates to the use of physically-based Regional Climate Models
(RCM). RCMs are climate models with a higher spatial resolution than GCMs. The modelled area
is limited in space and time-dependant boundary conditions are provided and driven by GCMs.
According to Fowler et al. (2007a), RCMs typically provide climatic simulations at a ~0.5°
latitude and longitude scale. First climate applications using RCMs were performed by Dickinson
et al. (1989) and Giorgi (1990). The complexity and number of climate processes included in
RCMs have then progressively increased. Compared to GCMs, RCMs can take into account
some additional regional features such as, for example, topography, vegetation cover, presence of
lakes, etc., which improves the performance of RCMs in reproducing regional climate and
extreme events. The European FP5 PRUDENCE project (Prediction of Regional scenarios and
Uncertainties for defining European Climate change risks and Effect) (Christensen et al., 2007)
produced such kind of high spatial resolution simulations for an ensemble of RCMs, using
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different GCMs boundary conditions and greenhouse gases emission scenarios (see Section
2.3.3). However, RCMs also suffer from various drawbacks. As GCMs, Regional Climate Models
are computationally expensive and simulations are usually limited in simulated time. In the
context of climate change, simulations are typically performed only for the time slices 1961-1990,
representing a climate without any change, and 2070-2100, representative of a stationary climate
change over the 30-years period of the end of the century. Another major drawback is link to the
fact that RCMs results are strongly dependent on the driving boundary conditions selected from
GCMs. Though more accurate than GCMs, the use of Regional Climate Models is usually not
sufficient to produce climatic scenarios for local hydrological studies and further statistical
downscaling is generally required.
'Statistical downscaling' is based on empirical or statistical relationships betweens GCMs or
RCMs outputs and the local climate to be simulated. Typically, relationships are defined between
a GCM or RCM 'control simulation' without any climate change and observed climatic data from
a local measurement station. To generate climate change scenarios, the same relationships are
then used but with the corresponding GCM or RCM outputs that consider a specific climate
change. Statistical downscaling methods allow providing climatic scenarios at the very local scale
needed for most hydrological studies. They also have the advantage of being computationally
inexpensive and quite flexible. Nevertheless, they can only be applied where observed climatic
data are available in sufficient quantities. According to Fowler et al. (2007a) and IPCC (2001b;
2007b), there exist a huge range of different statistical downscaling methods, from very simple to
highly complex models involving large numbers of variables and parameters. They allow
modelling local climate with various degrees of complexity. Fowler et al. (2007a) classify statistical
downscaling methods into three main categories: the 'regression models', the 'weather typing
schemes' and the 'weather generators' techniques. Briefly, the 'regression' or 'transfer function'
methods use direct relationships between GCM or RCM variables (the 'predictors') and local
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climate variables (the 'predictants') through the use of regression methods, for example. The
'weather typing scheme' relates to the occurrence of particular 'weather classes' to local climate
(Fowler et al., 2007a). Various methods exist for defining these 'weather classes', specifically for
the downscaling purposes. The 'weather generators' (Wilks and Wilby, 1999) are statistical models
that enable to generate climate scenarios based on the statistical distributions of a series of
climatic variables. Each distribution is determined using observed local climatic data and can be
modified based on GCMs or RCMs outputs. The 'weather generators' have the great advantage
that they enable to easily generate large numbers of stochastic climatic scenarios, that can be used
in subsequent probabilistic analyses of climatic variables or any potential impact.
To date, studies examining the impacts of climate change on groundwater systems have adopted
relatively simple statistical downscaling methods. One of the most straightforward approaches is
the 'perturbation' or 'delta change' method (Prudhomme et al., 2002) which applies 'change
factors' (CFs), calculated as difference between the control and future GCM simulations, to
observations (e.g. Brouyère et al., 2004b; Yusoff et al., 2002). However, since these scenarios
were produced by applying the projected changes to mean temperature and precipitation to the
whole of the corresponding future distribution, they fail to reflect changes in the shape of the
distribution, which is important for extremes or changes in the distribution of wet and dry
periods. In their impact study concerning groundwater in the Grand Forks aquifer, Scibek and
Allen (2006b) use the 'LARS-WG' weather generator (Semenov et al., 1998) to generate a single
100-years scenario representing a stationary climate for each of the periods 2010-2039, 2040-2069
and 2070-2099. (Holman et al., 2009) use the 'CRU' weather generator (Kilsby et al., 2007; Watts
et al., 2004) to produce 100 realisations of 30-years scenarios for the period 2040-2069 and use
them as input of a one-dimensional soil water balance to calculate groundwater recharge.
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2.3.3 Greenhouse gases emissions scenarios
As briefly explained above, a large panel of climate models is available to produce climatic
simulations in relation with objectives and needs of specific studies. More particularly, they are
widely used to generate climate change scenarios for climate change impact studies, based on
CO2 and other greenhouse gases emissions, among others. The Intergovernmental Panel on
Climate Change (IPCC) developed a set of emissions scenarios known as the SRES scenarios
(Special Report on Emission Scenarios) (IPCC, 2000). All scenarios are regrouped within 4
different storylines which describe the context of the emission scenarios in various domains such
as economy, technology, demography, etc. These four storylines are described in details by IPCC
(2000). Main characteristics are summed up in Table 2.2. Figure 2.2 (IPCC, 2000) shows the
range of projected CO2 emissions between 1990 and 2100 for each of the four storylines. The
sets of greenhouse gases emission scenarios, available for each storyline, can then be used in
GCMs to produce climate change scenarios for specific climatic variables. As an illustration, the
different existing GCMs used with the A2 emission scenarios project a global temperature
increase between 1.3°C and 4.5°C for the period 2070-2100 relatively to the period 1961-1990.
The global temperature increase for the B2 emission scenarios varies between 0.9°C and 3.4°C.
Generally, the increase is expected to be higher for Northern Europe (IPCC, 2000; IPCC,
2001b).
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Storyline A1
- World that becomes more homogeneous with increased social and cultural interactions
- Very rapid economic growth
- Global population that peaks in mid-century and declines after
- Rapid introduction of new and more efficient technologies
Scenario A1 is divided into 3 sub-categories based on their energy sources: fossil intensive (A1F1), non-fossil energy sources (A1T), balance across all sources (A1B)
Storyline A2
- Very heterogeneous world with self-reliance and preservation of local identities
- Regionally oriented economic development
- Global population that continuously increases
- More fragmented and slower technological change than other scenarios
Storyline B1
- World that becomes more homogeneous
- Rapid change in economic structures toward a service and information economy, with reductions in material intensity
- Global population that peaks in mid-century and declines after
- Introduction of clean and resource-efficient technologies
Storyline B2
- Heterogeneous world
- Emphasis is on local solutions to economic, social and environmental sustainability
- Global population that continuously increases, but at a lower rate than scenario A2
- Less rapid and more diverse technological change than in the scenarios A1 and B1
Table 2.2. SRES emissions scenarios (IPCC, 2000)
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Figure 2.2. (Figure and legend from IPCC, 2000) Total global annual CO2 emissions from all sources (energy, industry, and land-use change) from 1990 to 2100 (in gigatonnes of carbon (GtC/yr)) for the
families and six scenario groups. […] Each coloured emission band shows the range of harmonized and non-harmonized scenarios within each group. For each of the six scenario groups an illustrative scenario is
provided (solid and dashed lines). […]
2.4 Evaluation of the uncertainty linked to climate change impact
While climate change impact studies focussing on groundwater reserves are not frequent, those
which attempt to assess the uncertainty of the impact estimations are even less common. To be
more specific, most existing studies actually take into account some kind of uncertainty, by using
multiple GCMs or RCMs. As explained above, climatic models can represent atmospheric
processes differently, through different numerical schemes or parameterisations. Testing an
ensemble of climatic models as input of the hydrological model enables to assess the uncertainty
linked to climate modelling. To go further in the analysis, a few studies also use climatic models
representative of different greenhouse gases emissions scenarios, which allows considering
additional uncertainty (e.g. Holman, 2006; Yusoff et al., 2002). However, in all studies, the
analysis is limited to sources of uncertainty related with the modelling of climatic conditions.
Existing climate change impact studies do not consider uncertainty at other levels, such as the
2. Scientific review
43
uncertainty linked to hydrological modelling, which could have a significant impact. Holman
(2006) also widens the discussion beyond the strict implication of direct climate impacts, by
identifying a series of possible indirect effects mostly related to socio-economic change in human
societies (e.g. land use change, increase of the water demand, change in agricultural practices,
etc.).
2. Scientific review
44
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Batelaan, O. and De Smedt, F., 2001. WetSpass: a flexible, GIS based, distributed recharge methodology for regional groundwater modelling. In: H. Gehrels et al. (Editors), Sixth IAHS Scientific Assembly. Impact of Huyman Activity on Groundwater Dynamics. IAHS, Maastrich (The Netherlands), pp. 11-17.
Brouyère, S., 2001. Etude et modélisation du transport et du piégeage des solutés en milieu souterrain variablement saturé (Study and modelling of transport and retardation of solutes in variably saturated media). PhD Thesis, University of Liège, Liège (Belgium), 640 pp.
Brouyère, S., Carabin, G. and Dassargues, A., 2004b. Climate change impacts on groundwater resources: modelled deficits in a chalky aquifer, Geer basin, Belgium. Hydrogeology Journal, 12: 123-134.
Carabin, G. and Dassargues, A., 1999. Modeling groundwater with ocean and river interaction. Water Resources Research, 35(8): 2347-2358.
Chen, Z., Grasby, S.E. and Osadetz, K.G., 2002. Predicting average annual groundwater levels from climatic variables: an empirical model. Journal of Hydrology, 260: 102-117.
Chen, Z., Grasby, S.E. and Osadetz, K.G., 2004. Relation between climate variability and groundwater levels in the upper carbonate aquifer, southern Manitoba, Canada. Journal of Hydrology, 290: 43-62.
Christensen, J.H., Carter, T.R., Rummukainen, M. and Amanatidis, G., 2007. Evaluating the performance and utility of regional climate models: The PRUDENCE project. Climatic Change, 81(Supplement 1): 1-6.
Christensen, N.S., Wood, A.W., Voisin, N., Lettenmaier, D.P. and Palmer, R.N., 2004. Effects of climate change on the hydrology and water resources of the Colorado river basin. Climatic Change, 62: 337-363.
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Deque, M., Dreveton, C., Braun, A. and Cariolle, D., 1994. The ARPEGE/IFS Atmosphere Model - A contribution to the french community climate modeling. Climate Dynamics, 10(4-5): 249-266.
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Eckhardt, K. and Ulbrich, U., 2003. Potential impacts of climate change on groundwater recharge and streamflow in a central European low mountain range. Journal of Hydrology, 284(1-4): 244-252.
Fowler, H.J., Blenkinsop, S. and Tebaldi, C., 2007a. Linking climate change modelling to impacts studies: recent advances in downscaling techniques for hydrological modelling. International Journal of Climatology, 27(12): 1547-1578.
Fowler, H.J., Kilsby, C.G. and O'Connell, P.E., 2003. Modelling the impacts of climatic change and variability on the reliability, resilience and vulnerability of a water resource system, Water Resources Research, pp. 10.
Fowler, H.J., Kilsby, C.G. and Stunell, J., 2007b. Modelling the impacts of projected future climate change on water resources in northwest England. Hydrology and Earth System Sciences, 11(3): 1115-1126.
Gellens, D. and Roulin, E., 1998. Streamflow response of Belgian catchments to IPCC climate change scenarios. Journal of Hydrology, 210: 242-258.
Giorgi, F., 1990. Simulation of regional climate using a limited area model nested in a general-circulation model. Journal of Climate, 3(9): 941-963.
Gordon, C., Cooper, C., Senior, C.A., Banks, H., Gregory, J.M., Johns, T.C., Mitchell, J.F.B. and Wood, R.A., 2000. The simulation of SST, sea ice extents and ocean heat transports in a version of the Hadley Centre coupled model without flux adjustments. Climate Dynamics, 16(2): 147-168.
Graham, D.N. and Butts, M.B., 2006. Flexible, integrated watershed modelling with MIKE SHE. In: V.P. Singh and D.K. Frevert (Editors), Watershed Models. CRC Press.
Grotch, S.L. and MacCracken, M.C., 1991. The Use of General Circulation Models to Predict Regional Climatic Change. Journal of Climate, 4(3): 286-303.
Harbaugh, A.W., 2005. MODFLOW-2005, The U.S. Geological Survey modular ground-water model - The Ground-Water Flow Process. U.S. Geological Survey Techniques and Methods 6-A16, U.S. Geological Survey.
Henriksen, H.J., Troldborg, L., Nyegaard, P., Sonnenborg, T.O., Refsgaard, J.C. and Madsen, B., 2003. Methodology for construction, calibration and validation of a national hydrologic model for Denmark. Journal of Hydrology, 280: 52-71.
Herrera-Pantoja, M. and Hiscock, K.M., 2008. The effects of climate change on potential groundwater recharge in Great Britain. Hydrological processes, 22(1): 73-86.
Holman, I., 2006. Climate change impacts on groundwater recharge- uncertainty, shortcomings, and the way forward? Hydrogeology Journal, 14(5): 637-647.
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Holman, I.P., Tascone, D. and Hess, T.M., 2009. A comparison of stochastic and deterministic downscaling methods for modelling potential groundwater recharge under climate change in East Anglia, UK: implications for groundwater resource management. Hydrogeology Journal, 17(7): 1629-1641.
IPCC, 2000. IPCC Special Report. Emission Scenarios. Cambridge University Press, Cambridge, United Kingdom, 570 pp.
IPCC, 2001. Climate Change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 881 pp.
IPCC, 2007. Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 996 pp.
Jiang, T., Chen, Y.D., Xu, C.-y., Chen, X., Chen, X. and Singh, V.P., 2007. Comparison of hydrological impacts of climate change simulated by six hydrological models in the Dongjiang Basin, South China. Journal of Hydrology, 336(3-4): 316-333.
Jones, J.-P., 2005. Simulating Hydrologic Systems Using a Physically-based Surface-Subsurface Model: Issues Concerning Flow, Transport and Parameterization. PhD Thesis, University of Waterloo, Waterloo (Canada), 145 pp.
Jyrkama, M.I. and Sykes, J.F., 2007. The impact of climate change on spatially varying groundwater recharge in the grand river watershed (Ontario). Journal of Hydrology, 338(3-4): 237-250.
Kilsby, C.G., Jones, P.D., Burton, A., Ford, A.C., Fowler, H.J., Harpham, C., James, P., Smith, A. and Wilby, R.L., 2007. A daily weather generator for use in climate change studies. Environmental Modelling & Software, 22(12): 1705-1719.
Kollet, S.J. and Maxwell, R.M., 2006. Integrated surface-groundwater flow modeling: A free-surface overland flow boundary condition in a parallel groundwater flow model. Advances in Water Resources, 29(7): 945-958.
Kollet, S.J. and Maxwell, R.M., 2008. Capturing the influence of groundwater dynamics on land surface processes using an integrated, distributed watershed model. Water Resour. Res., 44.
Li, Q., Unger, A.J.A., Sudicky, E.A., Kassenaar, D., Wexler, E.J. and Shikaze, S., 2008. Simulating the multi-seasonal response of a large-scale watershed with a 3D physically-based hydrologic model. Journal of Hydrology, 357(3-4): 317-336.
Loáiciga, H.A., 2003. Climate Change and Ground Water. Annals of the Association of American Geographers, 93(1): 30-41.
Loaiciga, H.A., Maidment, D.R. and Valdes, J.B., 2000. Climate-change impacts in a regional karst aquifer, Texas, USA. Journal of Hydrology, 267: 173-194.
Martin, G. et al., 2004. Evaluation of the Atmospheric Performance of HadGAM/GEM1, Hadley Center for Climate Change and Research/MET Office, Exeter, UK.
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McFarlane, N.A., Boer, G.J., Blanchet, J.P. and Lazare, M., 1992. The Canadian Climate Center 2nd-Generation General-Circulation Model and its Equilibrium Climate. Journal of Climate, 5(10): 1013-1044.
Pope, V.D., Gallani, M.L., Rowntree, P.R. and Stratton, R.A., 2000. The impact of new physical parametrizations in the Hadley Centre climate model: HadAM3. Climate Dynamics, 16(2): 123-146.
Prudhomme, C., Reynard, N. and Crooks, S., 2002. Downscaling of global climate models for flood frequency analysis: where are we now? Hydrological processes, 16(6): 1137-1150.
Refsgaard, J.C. and Storm, B., 1995. MIKE SHE. In: V.P. Singh (Editor), Computer Models of Watershed Hydrology. Water Resources Publications, Highlands Ranch, Colorado, pp. pp. 809-846.
Roeckner, E. et al., 1996. The atmospheric general circulation model ECHAM-4: model description and simulation of present-day climate. Report n° 218, Max-Planck Institute for Meteorology, Hamburg, Germany.
Roeckner, E. et al., 2003. The Atmospheric General Circulation Model ECHAM5. Part I: Model Description. MPI Report 349, Max-Planck Institute for Meteorology, Hamburg, Germany.
Schaffranek, R.W., Baltzer, R.A. and Goldberg, D.E., 1981. A model for simulation of flow in singular and interconnected channels. U.S. Geological Survey, Techniques of Water-Resources Investigations, Book 7, Chapter C3, U.S. Geological Survey, USA.
Schroeder, P.R., Dozier, T.S., Zappi, P.A., McEnroe, B.M., Sjostrom, J.W. and Peyton, R.L., 1994. The Hydrologic Evaluation of landfill Performance (HELP) model: Engineering documentation for version 3. Rep. EPA/600/R-94/168b, U.S. Environmental Protection Agency, Washington (D.C., USA).
Scibek, J. and Allen, D.M., 2006a. Comparing modelled responses of two high-permeability, unconfined aquifers to predicted climate change. Global and Planetary Change, 50(1-2): 50-62.
Scibek, J. and Allen, D.M., 2006b. Modeled impacts of predicted climate change on recharge and groundwater levels. Water Resources Research, 42: 18.
Scibek, J., Allen, D.M., Cannon, A.J. and Whitfield, P.H., 2007. Groundwater-surface water interaction under scenarios of climate change using a high-resolution transient groundwater model. Journal of Hydrology, 333(2-4): 165-181.
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Serrat-Capdevila, A., Valdés, J.B., Pérez, J.G., Baird, K., Mata, L.J. and Maddock Iii, T., 2007. Modeling climate change impacts - and uncertainty - on the hydrology of a riparian system: The San Pedro Basin (Arizona/Sonora). Journal of Hydrology, 347(1-2): 48-66.
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Sonnenborg, T.O., Christensen, B.S.B., Nyegaard, P., Henriksen, H.J. and Refsgaard, J.C., 2003. Transient modeling of regional groundwater flow using parameter estimates from steady-state automatic calibration. Journal of Hydrology, 273(1-4): 188-204.
Sudicky, E.A., Jones, J.-P., Park, Y.-J., Brookfield, E.A. and Colautti, D., 2008. Simulating complex flow and transport dynamics in an integrated surface-subsurface modeling framework. Geosciences Journal, 12(2): 107-122.
Therrien, R., McLaren, R.G., Sudicky, E.A. and Panday, S.M., 2005. HydroGeoSphere. A three-dimensional numerical model describing fully-integrated subsurface and surface flow and solute transport, 343 pp.
Van Roosmalen, L., Christensen, B.S.B. and Sonnenborg, T.O., 2007. Regional Differences in Climate Change Impacts on Groundwater and Stream Discharge in Denmark. Vadose Zone J, 6(3): 554-571.
Van Roosmalen, L., Sonnenborg, T.O. and Jensen, K.H., 2009. Impact of climate and land use change on the hydrology of a large-scale agricultural catchment. Water Resources Research, 45.
VanderKwaak, 1999. Numerical Simulation of Flow and Chemical Transport in Integrated Surface-Subsurface Hydrologic Systems, University of Waterloo, Waterloo, Ontario, Canada, 242 pp.
VanRheenen, N.T., Wood, A.W., Palmer, R.N. and Lettenmaier, D.P., 2004. Potential Implications of PCM Climate Change Scenarios for Sacramento–San Joaquin River Basin Hydrology and Water Resources. Climatic Change, 62(1): 257-281.
Watts, M., Goodess, C.M. and Jones, P.D., 2004. Validation of the CRU daily weather generator. BETWIXT Technical Briefing Note 4, Climatic Research Unit, University of East Anglia.
Wilby, R.L., Whitehead, P.G., Wade, A.J., Butterfield, D., Davis, R.J. and Watts, G., 2006. Integrated modelling of climate change impacts on water resources and quality in a lowland catchment : River Kennet, UK. Journal of Hydrology, 330(1-2): 204-220.
Wilby, R.L. and Wigley, T.M.L., 1997. Downscaling general circulation model output: a review of methods and limitations. Progress in Physical Geography, 21(4): 530-548.
Wilks, D.S. and Wilby, R.L., 1999. The weather generation game: a review of stochastic weather models. Progress in Physical Geography, 23(3): 329-357.
Woldeamlak, S., Batelaan, O. and De Smedt, F., 2007. Effects of climate change on the groundwater system in the Grote-Nete catchment, Belgium. Hydrogeology Journal, 15(5): 891-901.
Yan, J.S. and Smith, K.R., 1994. Simulation of integrated surface-water and ground-water systems - Model formulation. Water Resources Bulletin, 30(5): 879-890.
Yusoff, I., Hiscock, K.M. and Conway, D., 2002. Simulation of the impacts of climate change on groundwater resources in eastern England. Geological Society, London, Special Publications, 193(1): 325-344.
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3. METHODOLOGY
3. Methodology
50
3. Methodology
51
3.1 Methodology
The objective of this thesis is to provide improved methods for the estimation of the impacts of
climate change on groundwater reserves, by developing an innovative modelling approach that
alleviates the simplifying assumptions presented in Section 2 through the review of the scientific
literature. This new approach includes providing improvements and innovations at three levels:
1. Hydrological modelling.
2. Use of climate change modelling and downscaling techniques.
3. Methods that allow evaluating uncertainties of various types.
1. To demonstrate the approach, the numerical model 'HydroGeoSphere' (Therrien et al., 2005)
has been used to develop catchment-scale simulation of coupled surface and subsurface water
flow in the Geer basin located in the Walloon Region of Belgium. 'HydroGeoSphere', which
enables to perform physically-based and spatially-distributed simulations, provides a realistic
representation of the system, compared to simplified models that are inadequate if the water
fluxes extrapolated in the climate change scenarios and imposed to the hydrologic system are not
included in the intervals of values used in the calibration procedure. The model developed in this
study fully integrates surface- and subsurface- flow in the saturated and partially saturated zones,
with a simultaneous solution of the flow equations in all domains using finite elements. As
already pointed out in Section 2, this simultaneous solution enables a better representation of the
whole system because water flow in one domain is interconnected with flow in the other
domains. Water exchange between the surface and subsurface is calculated internally at each time
step. Similarly, the actual evapotranspiration is calculated internally as a function of the soil
moisture at each node of the defined evaporative zone and at each time step. Integrating
evapotranspiration, surface, and subsurface flow calculations in the same model does not only
increase the complexity of the model, which would not guarantee more robust predictions (Ebel
3. Methodology
52
and Loague, 2006), but also increases the number of observed data available for calibration.
Because both surface and subsurface data are used for calibration, parameter values are better
constrained, and the uncertainty in the estimation of some components of the global water
balance is reduced. In particular, recharge and surface water – groundwater interactions are better
represented, which is crucial in the context of a climate change impact study on groundwater
reserves.
2. The climate change scenarios, to be applied as input of the Geer basin hydrological model,
have been generated from state-of-the-art RCMs simulations, using two different downscaling
techniques: the 'quantile mapping bias-correction' technique (Wood et al., 2004) and the 'CRU
weather generator' (Kilsby et al., 2007; Watts et al., 2004). These two downscaling techniques
have the great advantage, compared to other downscaling techniques usually used in hydrological
studies, that they not only apply a correction to the mean of climatic variables, but also across the
statistical distributions of these variables. This seems crucial to achieve a reliable climate change
impact study as the distribution of precipitation, for example, is expected to change in the future,
with more intense rainfall events separated by longer dry periods. This change in distribution may
actually have a significant impact on the dynamic of runoff and groundwater infiltration. The
'quantile mapping bias-correction' technique is used to generate climatic variables time series
representative of a stationary climate for the periods 2011-2040, 2041-2070 and 2071-2100. The
'CRU' weather generator is used to generate a large number of equiprobable transient climate
change scenarios between 2010 and 2085. All these downscaled scenarios are then applied as
input of the Geer basin hydrological model to evaluate climate change impact on groundwater
resources.
3. Uncertainty is evaluated regarding different possible sources, at different levels between the
modelling of the climate at the scale of the earth globe and the modelling of hydrological
conditions at the scale of the catchment.
3. Methodology
53
- First, climate change scenarios are downscaled from various RCMs, with boundary conditions
from different GCMs. Using data from several climate models allows evaluating the
uncertainty related to the modelling of atmospheric conditions at the scale of the earth globe
(GCMs) and at the regional scale (RCMs).
- Second, two different methods (the 'quantile mapping bias-correction' and 'CRU weather
generator' techniques) are used to downscale climatic data from large to catchment scale.
Using both types of downscaled climatic scenarios as input of the Geer basin model will
enable to highlight possible differences due to the downscaling method.
- Third, large numbers of equiprobable climate change scenarios from 2010 to 2085 are
generated using the 'CRU weather generator' technique and applied as input of the Geer basin
hydrological model. The objective is to estimate the uncertainty of projected groundwater
levels, in relation to the natural variability of the climate. Because the number of climate
change scenarios is large, statistical tools can then be used to calculate, for each specific time
between 2010 and 2085, the variance of simulated groundwater levels and associated
confidence intervals.
- The previous steps described above relate to the uncertainty linked to the modelling of
climatic conditions. However, additional source of uncertainty is also linked to the use to the
Geer basin hydrological model. Numerical models are actually simplifications of the reality.
No calibration is perfect and it has some implications on the accuracy of models predictions.
In this study, the computer code 'UCODE_2005' (Hill and Tiedeman, 2007; Poeter et al.,
2005) is used to evaluate this kind of uncertainty linked to the model calibration.
UCODE_2005 has been developed by the 'U.S. Geological Survey' (USGS), and can be
coupled with other modelling codes to perform sensitivity analysis, data needs assessment,
automatic inverse calibration, prediction and uncertainty analysis. In the context of this study,
3. Methodology
54
linear confidence intervals are calculated for predicted groundwater levels under climate
change conditions. To corroborate the analysis, climate change impact on groundwater levels
are also evaluated using two Geer basin hydrological models with unequal calibrations.
Discrepancies are then examined and compared with the linear confidence intervals calculated
with 'UCODE_2005'.
The implementation of the integrated surface – subsurface model with 'HydroGeoSphere' is
presented with many details in Section 5. An important part of the section is also devoted to the
evaluation of the model calibration. Section 6 describes the used climate models (GCMs and
RCMs), the 'quantile mapping bias-correction' downscaling technique, and the application of the
downscaled scenarios as input of the Geer basin model. Section 7 describes the 'CRU weather
generator', the application of stochastic climate change scenarios on the Geer basin model, and
subsequent interpretations of the results. The first part of Section 8 presents the coupling of
'UCODE_2005' with the Geer basin model to estimate the uncertainty linked to the calibration
of the hydrological model. The second part of Section 8 summarises and discusses all results
about impact uncertainty.
3. Methodology
55
3.2 References
Ebel, B.A. and Loague, K., 2006. Physics-based hydrologic-response simulation: Seeing through the fog of equifinality. Hydrological processes, 20(13): 2887-2900.
Hill, M.C. and Tiedeman, C.R., 2007. Effective groundwater model calibration. With Analysis of data, sensitivities, predictions and uncertainty. John Wiley & Sons, New Jersey, 455 pp.
Kilsby, C.G., Jones, P.D., Burton, A., Ford, A.C., Fowler, H.J., Harpham, C., James, P., Smith, A. and Wilby, R.L., 2007. A daily weather generator for use in climate change studies. Environmental Modelling & Software, 22(12): 1705-1719.
Poeter, E.P., Hill, M.C., Banta, E.R., Mehl, S. and Christensen, S., 2005. UCODE_2005 and Six Other Computer Codes for Universal Sensitivity Analysis, Calibration, and Uncertainty Evaluation: U.S. Geological Survey Techniques and Methods 6-A11, 283 pp.
Therrien, R., McLaren, R.G., Sudicky, E.A. and Panday, S.M., 2005. HydroGeoSphere. A three-dimensional numerical model describing fully-integrated subsurface and surface flow and solute transport, 343 pp.
Watts, M., Goodess, C.M. and Jones, P.D., 2004. Validation of the CRU daily weather generator. BETWIXT Technical Briefing Note 4, Climatic Research Unit, University of East Anglia.
Wood, A.W., Leung, L.R., Sridhar, V. and Lettenmaier, D.P., 2004. Hydrologic Implications of Dynamical and Statistical Approaches to Downscaling Climate Model Outputs. Climatic Change, 62(1): 189-216.
3. Methodology
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4. The Geer basin
57
4. THE GEER BASIN
4. The Geer basin
58
4. The Geer basin
59
4.1 Geographical and geological contexts
The Geer sub-catchment is located in eastern Belgium, north-west of the city of Liège, in the
intensively cultivated 'Hesbaye' region. The hydrological basin extends over approximately 480
km², on the left bank of the Meuse River (Figure 4.1).
Figure 4.1. Location of the Geer basin and hydrologic limits.
The geology of the Geer basin essentially consists of Cretaceous chalky formations that dip
northward and that are bounded at their base by 10 metres of smectite clays of very low hydraulic
conductivity (Figure 4.2). The chalk formation consists of a series of chalk layers, whose
thicknesses range from a few meters up to 70 m. This formation can be divided into two main
groups, the Campanian lower chalks and the Maastrichtian upper chalks. A flint conglomerate of
dissolved chalk residues overlies the chalk, with a maximum thickness of 10 m. Tertiary sand
lenses of small extension are found locally above this conglomerate and a thick layer (up to 20 m)
of Quaternary loess is observed throughout the catchment. Tertiary sands and clays entirely cover
the chalk formations north of the Geer River (Figure 4.2) (Hallet, 1998; Orban et al., 2006).
4. The Geer basin
60
Figure 4.2. Geological cross-section in the Hesbaye aquifer (modified from (modified from Brouyère et al.,
2004b)), with a vertical exaggeration equal to 40.
4.2 Hydrogeological context
The main aquifer in the region is the ‘Hesbaye’ aquifer, which corresponds to the chalk layers and
is unconfined over most of the basin. Subsurface flow is from south to north and the aquifer is
mainly drained by the Geer River that flows from west to east, as shown at Figure 4.3 (Orban,
2009; Orban et al., 2006; Ruthy, 2009). The chalk porous matrix, whose total porosity is
estimated equal to 44%, enables the storage of large quantities of groundwater, while fast
preferential flow occurs through fractures, which represent approximately 1% of the total
porosity (Brouyère, 2001; Hallet, 1998). At a macroscopic scale, the hydraulic properties of the
chalk formations vary vertically and laterally. The lower Campanian chalks are usually less
permeable than the upper Maastrichtian chalks. Laterally, zones of higher hydraulic conductivity
are observed and associated with 'dry valleys', mostly oriented south to north. These zones,
characterized by a higher degree of fracturing, are associated with a slight lowering of hydraulic
4. The Geer basin
61
heads. For the larger part of the Geer catchment, the saturated zone is exclusively located in the
chalk formations. The thick loess layer located above the chalk controls the water infiltration rate
from the land surface to the chalky aquifer, resulting in smoothed recharge fluxes at the
groundwater table and attenuation of seasonal fluctuations of hydraulic heads that are better
characterised by multi-annual variations (Brouyère et al., 2004a). As an illustration, Figure 4.4
shows the evolution of groundwater levels at the observation well 'VIE004' (Figure 4.1) from
1950 to 2006. In the northern part of the catchment, near the Geer River, water levels are closer
to the ground surface and semi-confined conditions may prevail because of the loess Quaternary
deposits. North of the Geer River, Tertiary deposits become thicker and contain some clearly
clayey layers. These layers are responsible for the confined nature of the chalky aquifer at this
location (Figure 4.2).
Figure 4.3. Piezometry of the chalk aquifer (in metres above sea level) based on 2088 data (modified from
Orban, 2009; Ruthy, 2009).
The ‘Hesbaye’ aquifer is largely exploited for drinking water, primarily through a network of
pumping galleries of more than 40 km that is located in the saturated chalk formation (Figure
4. The Geer basin
62
4.1). Most of this water is used to supply the city of Liège and its suburbs. A part of drained
water is transported by gravity, but some pumping is also carried out directly in the galleries to
provide drinking water to local communities or to lift up water into more elevated aqueducts.
The draining galleries can also be "switched on" or "switched off" in function of the water needs
or nitrate content (Hodiaumont et al., 1999; Orban, 2009). According to Hallet (1998), extracted
groundwater volumes represent between 6% and 11% of annual precipitations. The groundwater
budget (Hallet, 1998) also indicates groundwater losses mostly through the northern catchment
boundary, and partly resulting from groundwater extraction in the Flemish region of Belgium
located directly north of the Geer basin. According to (Hallet, 1998), the water budget of the
Geer basin for the period 1975-1994, is distributed in 63% of evapotranspiration, 18% of river
discharge at the outlet of the catchment, 11% of groundwater abstraction and 7% of groundwater
losses through the northern boundary.
The Hesbaye aquifer suffers from severe nitrate contamination problems, due to intensive
agricultural activities. In the Geer basin, 77% of the area is actually devoted to crops, mainly for
the cultivation of cereals and sugar beets. In many locations in the unconfined part of the aquifer,
nitrate concentrations are frequently over 45 mg/L, approaching the drinking water limit of 50
mg/L (Batlle-Aguilar et al., 2007; Hallet, 1998).
4. The Geer basin
63
Figure 4.4. Evolution of groundwater levels at the observation well 'VIE044', from 1950 to 2006.
4. The Geer basin
64
4.3 References
Batlle-Aguilar, J., Orban, P., Dassargues, A. and Brouyère, S., 2007. Identification of groundwater quality trends in a chalk aquifer threatened by intensive agriculture in Belgium. Hydrogeology Journal, 15(8): 1615-1627.
Brouyère, S., 2001. Etude et modélisation du transport et du piégeage des solutés en milieu souterrain variablement saturé (Study and modelling of transport and retardation of solutes in variably saturated media). PhD Thesis, University of Liège, Liège (Belgium), 640 pp.
Brouyère, S., Carabin, G. and Dassargues, A., 2004a. Climate change impacts on groundwater resources: modelled deficits in a chalky aquifer, Geer basin, Belgium. Hydrogeology Journal, 12: 123-134.
Brouyère, S., Dassargues, A. and Hallet, V., 2004b. Migration of contaminants through the unsaturated zone overlying the Hesbaye chalky aquifer in Belgium: a field investigation. Journal of Contaminant Hydrology, 72(1-4): 135-164.
Hallet, V., 1998. Etude de la contamination de la nappe aquifère de Hesbaye par les nitrates: hydrogéologie, hydrochimie et modélisation mathématique des écoulements et du transport en milieu saturé (Contamination of the Hesbaye aquifer by nitrates: hydrogeology, hydrochemistry and mathematical modeling). PhD Thesis, University of Liège, Liège (Belgium), 361 pp.
Hodiaumont, A., Cantillana, R. and Compère, J.M., 1999. Les eaux souterraines de la CILE : Contexte, captage et qualité. Tribune de l'eau, 52(600-601): 31-50.
Orban, P., 2009. Solute transport modelling at the groundwater body scale: Nitrate trends assessment in the Geer basin (Belgium). PhD Thesis, University of Liège, Faculty of Applied Sciences, Liège, 219 pp.
Orban, P., Batlle-Aguilar, J., Goderniaux, P., Dassargues, A. and Brouyère, S., 2006. Description of hydrogeological conditions in the Geer sub-catchment and synthesis of available data for groundwater modelling. Deliverable R3.16, AquaTerra (Integrated Project FP6 no 505428).
Ruthy, I., 2009. Carte hydrogéologique de Wallonie et notice explicative, Tongeren-Herderen 34/5-6. Service public de Wallonie, DGARNE, Namur.
5. Modelling
65
5. MODELLING
5. Modelling
66
5. Modelling
67
5.1 Hydrological modelling
5.1.1 Conceptual model
The Geer hydrological catchment defines the boundaries of the modelled area (Figure 4.1). The
smectite clay (Figure 4.2) is considered impervious and the contact between the clay and the
chalk represents the lower boundary of the model. The western, southern and eastern boundaries
correspond to surface water divides and it is assumed that there is no water exchange across these
boundaries for either surface or subsurface flow. On the other hand, groundwater fluxes through
the northern boundary must be taken into account. Along this border, hydrogeological and
hydrographical limits differ, and groundwater flows northwards towards the adjacent basin.
The Geer River at the level of the 'Kanne' gauging station, located 4 kilometres upstream from
the confluence with the Meuse River, is considered as the outlet of the catchment (Figure 4.1).
Surface water exchanges are not observed elsewhere along the model boundaries, since they
correspond to topographical limits.
Pumping wells operated by water supply companies or farmers are distributed over the whole
basin but water collected through the network of draining galleries is the largest component of
the total of groundwater abstraction in the Geer basin.
5.1.2 Mathematical and numerical model
The Geer basin hydrological model has been developed with the HydroGeoSphere finite element
model (Therrien et al., 2005). The spatially-distributed model simulates fully coupled 3D variably
saturated groundwater flow in granular or fractured aquifers and 2D overland flow, as well as
solute transport in the surface and subsurface domains. HydroGeoSphere simulates the dynamic
interactions between all sub-domains at each time step. It partitions rainfall into components
such as evapotranspiration, runoff and infiltration. The model also allows the calculation of water
5. Modelling
68
infiltration or exfiltration between rivers and aquifers. These interactions are of great interest in
the context of climate change as recharge is very sensitive to climatic variations and represent
crucial elements for impacts projections.
K Full Saturated hydraulic conductivity [L.T-1]
n Total porosity [-]
Ss Specific storage [L-1]
α Van van Genuchten parameter [-]
β Van van Genuchten parameter [L-1] Subs
urfa
ce d
omain
Swr Residual water saturation [-]
Lc Coupling length [L]
nx Manning roughness coefficient [L-1/3T]
Surf
ace
dom
ain
ny Manning roughness coefficient [L-1/3T]
Le Evaporation depth [L]
θe1 θe2 Evaporation limiting saturations [-]
LAI Leaf Area Index [-]
Lr Root depth [L]
C1, C2, C3 Transpiration fitting parameters [-]
θt1 θt2 Transpiration limiting saturations [-]
Eva
potra
npisr
atio
n
Cint Canopy storage parameter [L]
Table 5.1. Parameters used in the flow model
HydroGeoSphere uses the control volume finite element approach to simultaneously solve
Richards' equation describing 3D variably-saturated subsurface flow and a 2D depth-averaged
surface flow equation, which is the diffusion-wave approximation of the Saint Venant equation.
In the subsurface domain, the hydraulic head, the degree of saturation, and the water Darcy flux
are calculated at each node in the grid. In the surface domain, water depth (≈ height of water
above ground surface) and fluid flux are calculated for each node of the 2D grid. The stream
5. Modelling
69
locations can be implicitly retrieved by considering the surface nodes where the water depth is
greater than zero. Transport processes include advection, dispersion, retardation and decay.
Newton-Raphson iterations are used for solving non-linear equations. More information on the
model and equations solved is available in Therrien et al. (2005) and in Li et al (2008).
Hydrologic parameters required for the fully-coupled simulation are listed in Table 5.1 along with
their domain of application. It should be noted that fractures are not represented explicitly in the
Geer basin model, and equivalent porous media properties are assigned to the elements
representing the aquifer.
The Geer basin model uses a ‘dual-node approach’ to calculate water exchanges between the
surface and subsurface domains. In this approach, surface nodes have to coincide with nodes of
the subsurface grid topmost layer. Water flux between each corresponding surface and subsurface
nodes is calculated as the hydraulic head difference between the two domains multiplied by a
leakage factor (coupling length – Le [L]) characterising the properties of the soil. In
HydroGeoSphere, the model of Kristensen and Jensen (1975) is used to calculate the actual
transpiration Tp [LT-1] and evaporation Es [LT-1] as a function of the potential evapotranspiration
Ep [LT-1], the soil moisture at each node belonging to the specified evaporative and root zones,
and the 'Leaf Area Index' (LAI [-]) that represents the cover of leaves over a unit area (Equation
5.1 to 5.6) (Therrien et al., 2005). Equation 5.2 expresses the vegetation term, as a function of
LAI, and parameters C1 and C2. Full transpiration can occur if water saturation θ [-] is higher
than θt1 and there is no transpiration if water saturation is lower than θt2. Between these two
limiting saturations, transpiration decreases following a law governed by the parameters C3
(Equations 5.1 and 5.3). RDF(Lr) is the 'Root Distribution Function' that distributes the water
extracted from the root zone, along the root depth Lr [L], following a quadratic law. The quantity
of extracted water is more important near the surface and decreases with depth until zero at the
root depth Lr. The 'canopy evaporation Ecan [LT-1] corresponds to the evaporation of water
5. Modelling
70
intercepted by the canopy. Full evaporation can occur if water saturation is higher than θe1 and
there is no evaporation if water saturation is lower than θe2. Between these two limits, evaporation
decreases following a law governed by parameter C3 (Equations 5.4 and 5.5). EDF(Le) is the
'Evaporation Distribution Function' that distributes the water extracted from the evaporative
zone, along the evaporation depth (Le), following a quadratic law. The interception of
precipitation by the canopy is simulated by the bucket model, where precipitation in excess of
interception storage and evapotranspiration reaches the ground surface. The 'interception storage
capacity' maxintS [L] represents the maximum quantity of water that can be intercepted by the
canopy. It depends on LAI and the 'canopy storage parameter' cint [L] (Equation 5.6).
( ) [ ]canprp EELRDFfLAIfT −×××= )()( 21 θ (5.1)
( )[ ]{ }LAICCLAIf ×+= 121 ,1min,0max)( (5.2)
⎪⎪⎩
⎪⎪⎨
⎧
≤
≤≤⎥⎦
⎤⎢⎣
⎡−−
−
≤≤
=
θθ
θθθθθθθ
θθ
1
1221
1
2
2
1
1
003
t
tt
C
tt
t
t
for
for
for
f (5.3)
( ) [ ] ( )ecanps LEDFLAIfEEE ×−×−×= )(1* 1α (5.4)
⎪⎪⎩
⎪⎪⎨
⎧
>
≤≤−−
<
=
1
1221
2
2
1
0
*
e
eeee
e
e
for
for
for
θθ
θθθθθθθ
θθ
α (5.5)
LAIcS ×= intmaxint (5.6)
5. Modelling
71
5.1.3 Discretisation
A three-dimensional finite element mesh, composed of several layers of 6-node triangular
prismatic elements (Figure 5.1), was generated based on the conceptual model presented
previously. The elements have lateral dimensions equal to approximately 500 m. The top and
bottom layers of nodes represent the soil surface and the contact between smectite clay and
chalk, respectively. Subsurface formations are discretised using 11 finite element layers. Five
layers are used for the first five meters below the ground surface, with each layer having a
thickness of one meter. The finer vertical discretisation near ground surface represents more
accurately river – aquifer interactions as well as recharge processes at the interface between the
surface and subsurface domains. In particular, distributing several nodes vertically within the first
few meters below the ground surface enables the variation of evaporative and root depths, as well
as the vertical distribution of evapotranspiration rates, according to the land use and soil type.
The remaining lower six finite element layers are uniformly distributed vertically between the fifth
and bottom layers. A material is assigned to each 3D finite element based on data from more
than 120 boreholes distributed throughout the catchment. The ground surface is discretised using
one layer of 2D finite elements (Figure 5.1). The elevation of the surface nodes are calculated
using the Geer basin DTM (Digital Terrain Model), whose pixels have dimensions equal to
30 × 30 m. In the dual node approach, the nodes forming the surface domain correspond to the
node of the top layer of the subsurface domain. The total number of nodes for the subsurface
and surface domains is equal to 9420 and 785, respectively.
No-flow boundaries are applied to subsurface nodes belonging to the western, southern, eastern
and bottom boundaries. Cauchy conditions (head dependent flux) are applied on the subsurface
nodes along the northern boundary to take into account groundwater losses in the direction of
the adjacent catchment located northward from the Geer basin. For the surface flow domain, no-
flow Neumann boundary conditions are prescribed along the hydrographical limits of the Geer
5. Modelling
72
basin. Critical-depth boundary conditions are prescribed at the nodes corresponding to the
catchment outlet, at the level of the 'Kanne' gauging station. A critical-depth boundary condition
forces the water elevation at the boundary to be equal to the 'critical depth'. The 'critical depth' is
the water elevation for which the energy of the flowing water relatively to the stream bottom is
minimum (Hornberger et al., 1998; Therrien et al., 2005).
Figure 5.1. Spatial discretisation of the Geer basin
5.1.4 Specified Fluxes
Specified hydrological fluxes within the Geer catchment consist of precipitation,
evapotranspiration and groundwater abstraction by draining galleries and pumping wells.
5. Modelling
73
Historical climatic data are available for several weather stations located inside or near the Geer
basin1 (more details in Orban et al., 2006). The stations shown in Figure 4.1 have complete
precipitation (P) time series from 1960 to 2005. Temperature (T) and potential
evapotranspiration (PET) data, for the same time period, are available for the Bierset station only.
Data from these weather stations are used as inputs to the model and are applied on the surface
node layer as transient specified fluxes. Precipitation data from each station are distributed using
Thiessen polygons. Potential evapotranspiration data available only for the Bierset station are
assumed to be applicable to the whole catchment.
Extracted groundwater volumes, from the draining galleries and from the most important
production wells (Figure 4.1), have been collected by the Walloon administration and are updated
annually (Orban et al., 2006). Transient volumetric flow rates are prescribed at each node of the
3D grid corresponding to the draining galleries or the pumping wells locations.
5.1.5 Calibration procedure
The model was calibrated to observed hydraulic heads and surface flow rates during the period
1967-2003. A preliminary calibration was performed in steady state conditions, using the mean
data of the hydrologic year 1967-1968, and the results were used as initial conditions for the
transient simulations. Calibration further showed that inaccuracies in these initial conditions only
affect the simulation results on a short-term basis. Even with initial conditions very different
from reality, such as a fully saturated subsurface domain, induced differences are reduced within a
few days for surface water flow rates and within 2 years for groundwater hydraulic heads. The
transient flow model is calibrated to surface flow rates measured at the 'Kanne' gauging station
1 Historical climatic data for the Geer catchment were obtained from the Royal Meteorological Institute of Belgium (RMI).
5. Modelling
74
located on the Geer river at the catchment outlet, and to hydraulic heads from 8 observation
wells selected according to their location and the availability of measured hydraulic heads during
the calibration period (Figure 4.1). Specified fluxes are input on a daily basis, using total daily
precipitation, evapotranspiration and groundwater abstraction rates. Adaptive time-stepping is
used so that groundwater hydraulic heads and surface water elevations do not vary by more than
0.5 m and 0.01 m, respectively, during one time step. For the Geer basin model, time steps
commonly vary between a few minutes to a few hours.
5.1.5.1 Parameter values
In the subsurface domain, the Van Genuchten parameters are prescribed according to Brouyère
(2001) and Brouyère et al. (2004a). Table 5.2 summarizes the values used for the chalk and loess
formations. Saturated hydraulic conductivities are adjusted during calibration, taking into account
the extension of the geological units and the zones of higher hydraulic conductivity associated
with 'dry valleys'. The chalky aquifer is also vertically divided into 3 zones, namely 'upper chalk',
'intermediate chalk' and 'lower chalk'. This enables the represention of the decrease of saturated
hydraulic conductivity with depth. Adjusted values are also kept within ranges provided by the
measurements from laboratory and field tests conducted in the geologic formations of the Geer
basin, and by ranges of hydraulic conductivity values given by Hallet (1998), Brouyère (2001),
Brouyère et al. (2004a), and Dassargues and Monjoie (1993) for the Geer basin formations. Table
5.3 and Figure 5.2 summarize all saturated hydraulic conductivity values at the end of the
calibration.
Van Genuchten parameters Residual water saturation Total porosity Specific storage
α [m-1] β [-] Swr [-] n [-] Ss [m-1]
Chalk formations 0.099 1.10 0.023 0.44 1×10-4
Loess formations 7.57 1.16 0.024 0.41 1×10-4
Table 5.2. Van Genuchten parameters, total porosity and specific storage
5. Modelling
75
Name K [m.s-1]
Chalk 1 4×10-5 Chalk 2 1×10-3 Chalk 3 3×10-5 Chalk 4 2×10-6 Chalk 5 5×10-6 Lo
wer
cha
lk
Chalk – Dry valleys 2×10-4
Chalk 1 1×10-4 Chalk 2 1×10-3 Chalk 3 3×10-5 Chalk 4 1×10-4 Chalk 5 5×10-6
Inte
rmed
iate
chalk
Chalk – Dry valleys 2×10-4
Chalk 1 1×10-4 - 4×10-4 Chalk 2 1×10-3 Chalk 3 1×10-4 Chalk 4 1×10-4 Chalk 5 1×10-4 U
pper
cha
lk
Chalk – Dry valleys 2×10-4 - 5×10-4
Quaternary loess 1×10-8
Tertiary deposits 0.3×10-7 - 1×10-7
Table 5.3. Full saturated hydraulic conductivities values of the calibrated zones (results of calibration)
Figure 5.2. Distribution of the hydraulic conductivity zones for the chalk finite elements layers (results of
calibration)
5. Modelling
76
In the surface domain, the coupling length and the friction coefficients were adjusted according
to the soil2 and land use3 maps, respectively. The soil mean characteristics and thicknesses are
quite homogeneous at the scale of a 2D surface element in this model, since these characteristics
vary at a much smaller scale. The coupling length was therefore assumed constant everywhere
and equal to 0.01 m. Calibration later showed that the results were insensitive to the value of the
coupling length. Three categories of land-use, namely ‘rural’, ‘urban’ and ‘forested’, have been
identified and Manning's roughness coefficients were initially defined for each category. The
values of Manning's roughness coefficients obtained at the end of the calibration (Table 5.4) vary
between 0.03 and 0.6 [L-1/3T] which is consistent with values more commonly used in
hydrological models (Hornberger et al., 1998; Jones, 2005; Li et al., 2008).
nx - ny [s.m-1/3] Lc [m]
Rural 0.4 0.01
Urban 0.03 0.01
Forested 0.6 0.01
Table 5.4. Values for the Manning roughness coefficients and coupling length
The parameters used to calculate the actual evapotranspiration (Kristensen and Jensen, 1975)
were defined using values found in the scientific literature and are summarised in Table 5.5 for
four land-use categories (rural crop, rural grassland, rural broadleaf deciduous forested, urban).
Root depths range between 0 m and 5.2 m, according to values given by Canadell et al. (1996). A
uniform evaporation depth value of 2 m is assumed over the whole catchment. Values for the
maximum Leaf Area Index (LAI) are given by Scurlock et al. (2001), Asner et al. (2003), Vasquez
and Feyen (2003) and Li et al. (2008). Breuer et al. (2003) give maximum and minimum values of
2 © Direction Générale de l’Agriculture (Ministère de la Région Wallonne). Projet de Cartographie Numérique des sols de Wallonie (PCNSW). Projet du Gouvernement Wallon (GW VIII/2007/Doc.58.12/12.07/B.L & GW VII/2000/Doc.1331/07.12/JH.)
3 European Environment Agency (http://www.eea.europa.eu). Corine Land Cover Project. Copyright EEA, Copenhagen, 2007.
5. Modelling
77
the LAI throughout the year. For the Geer basin model, maximum LAI varies from 0.40 to 5.12.
In absence of information about minimum LAI for the vegetation of the Geer basin, LAI is
arbitrarily reduced by 50 % during the winter months. However, the results are insensitive to the
value of Min. LAI given that evapotranspiration is very low during winter months anyway. Values
for the empirical transpiration fitting parameters C1, C2 and C3, as well as for the canopy storage
interception Cint can be found in Kristensen and Jensen (1975) and Li et al. (2008). Used values of
C1, C2, C3 and Cint are equal to 0.3, 0.2, 10 and 1×10-5 m, respectively. The limiting saturations,
corresponding to the wilting point and field capacity, are specified as the saturations
corresponding to pF values4 equal to 4.2 and 2.5, as found in Brouyère (2001).
Rural crop (temperate)
Rural grassland (temperate)
Rural broadleaf deciduous forested
(temperate) Urban
Root depth Lr [m] 2.1 2.6 5.2 0.0
Evaporation depth Le [m] 2.0
Max. LAI [-] 4.22 2.50 5.12 0.40
Cint [m] 1×10-5
C1 [-] 0.3
C2 [-] 0.2
C3 [-] 10
Table 5.5. Root depths, evaporation depths and Leaf Area Index
4 pF=log(-hydraulic pressure)
5. Modelling
78
5.1.5.2 Evaluation of the calibration
Results of the steady state and transient simulations, using the calibrated parameters, are shown
in Figure 5.3 to Figure 5.6. Figure 5.3A presents the computed steady-state subsurface saturations
for the hydrological year 1967-1968. Similarly, Figure 5.3B shows the computed steady-state
water elevation at each node of the surface domain. The locations of the Yerne and the Geer
Rivers are clearly seen and correspond to the highest water elevations. The three graphs of Figure
5.4 present, in different ways, the computed and observed values following the methodology and
guidelines proposed by Hill & Tiedeman (2007) for a global assessment of the calibration. Figure
5.5 presents the measured and simulated transient hydraulic heads for the 8 selected observation
wells. Figure 5.6 presents the observed and simulated transient flow rates for the ‘Kanne’ gauging
station located at the outlet of the basin. Table 5.6 shows the mean absolute residuals, the mean
residuals and the weighted residuals for each observation point.
Data presented at Figure 5.4 consists in monthly mean hydraulic heads and flow rates. In this
first graph, monthly data are used because they are more representative of the general
fluctuations of groundwater reserves, which are the focus of this study. Daily data, and especially
daily surface flow rates, are however also presented in the next figures. Figure 5.4A shows
computed monthly hydraulic heads and flow rates along a line with slope equal to 1. This way of
presenting calibration results, commonly used by modellers, is not adequate because the large
ranges of simulated values tend to hide the potential calibration errors. Additionally, units and
order of magnitude can also differ if different kinds of observation data are used in the
calibration procedure. An alternative is to plot the residuals instead of computed values (Figure
5.4B) but it does not solve the problem of potentially different units. Hill & Tiedeman (2007)
propose to plot weighted residuals to assess the quality of the calibration and to evaluate some
important properties (Figure 5.4C). For each observation, weighted residuals are calculated
following Equation 5.1.
5. Modelling
79
Figure 5.3. (A) Computed steady-state surface water elevations. (B) Computed steady-state subsurface
saturation, with full saturation shown in red (1967-1968).
5. Modelling
80
Figure 5.4. Graphical analysis of the model calibration. (A) Computed values vs. observed values. (B)
Residuals vs. observed values. (C) Weighted residuals vs. observed values. Doted lines represent increments of the calculated standard error.
5. Modelling
81
( )( ) ( )( ) ( )( )byybyybyyw iii
iii
iii '1'1'2
1
22
1−×=−×⎟⎟
⎠
⎞⎜⎜⎝
⎛=−×
σσ (5.1)
iw : Weight for observation i
b : Vector of parameters
iy : Observed value i
iy' : Computed value i as a function of ( )b
2iσ : Variance of the true measurement errors of observation i
Using the inverse of the true measurement errors variance for weighting the residuals offers three
main advantages. First, weighted residuals are non dimensional and can be compared more easily.
Second, the weights enable to integrate in the analysis the uncertainty linked to the observations.
According to Equation 5.1, the weights associated with uncertain or inaccurately measured
observations will be less important and will then reduce the influence of the associated residual.
Third, this weighting scheme can be used in the calculation of the objective function when
performing a parameter optimisation. It allows calculating and interpreting very useful additional
statistics for sensitivity or prediction analysis, as used in Section 5.2 and Section 8.2. More details
in Hill & Tiedeman (2007). For the Geer basin model, the weights of the groundwater level
observations have been uniformly set to 3.84, considering the lack of information or particular
study about the true error of each observation. This weight value is based on the assumption that
the 95% confidence interval including the true groundwater level is within 1 metre around the
measured groundwater level. This confidence interval considers all types of possible errors:
measurement of the well top elevation, measurement of the groundwater depth, errors linked to
the precision of the measurement devices, encoding errors. Assuming that measurement errors
are normally distributed, the 95% confidence interval can easily be related to the variance. The
weights associated with the surface water flow rates at the outlet of the catchment vary between
5. Modelling
82
3.7 and 141.7. They have been calculated using a coefficient of variation of the measurement
errors equal to 10%. According to the team responsible of the measurement, this value is
considered as pertinent considering the measurement method used (personal communication).
Mean absolute residuals
( )N
hhN
i
compi
obsi∑ −
Mean residuals
( )N
hhN
i
compi
obsi∑ −
Mean weighted residuals
( )N
hhwN
i
compi
obsii∑ −2
1
A7-PL37 [m] 8.2 -8.2 -16.2
BOR009 [m] 4.0 -3.5 -7.0
CEL167 [m] 1.9 -0.3 -0.7
MOM001 [m] 3.0 1.1 2.2
OTH002 [m] 4.1 -2.1 -4.2
SLI006 [m] 3.3 2.6 5.3
VIE044 [m] 3.7 -2.9 -5.8
WIH014 [m] 5.3 -4.8 -9.5
Kanne [m³.s-1] 0.71 0.04 0.44
Table 5.6. Mean errors between observed and computed heads for the nine observation wells (hobs: observed hydraulic head, hcomp: computed hydraulic head, N: number of observations).
As shown in Table 5.6, the mean residual for all hydraulic heads is equal to -2.3 m, varying from -
8.2 m (A7-PL37) to 2.6 m (SLI006), and the mean residual for flow rate observations is equal to
0.04 m³/s. Similarly, the mean weighted residual for hydraulic heads and flow rate observations
are equal to -6.2 and 0.44, respectively. The mean weighted residual aggregating all types of
observations is equal to -5.2. Ideally, for the model being a consistent representation of the whole
hydraulic system, weighted residuals must be randomly distributed around zero (Hill and
Tiedeman, 2007). Here, the mean weighted residuals indicate that there is a negative bias in the
simulated groundwater levels. According to Figure 5.4C and Table 5.6, this negative bias is mainly
due to the simulated groundwater levels at A7-PL37 which severely underestimate observed
groundwater levels. These higher model errors at A7-PL37 could be explained by the proximity
5. Modelling
83
of the model borders, where the boundary conditions may not be verified locally, or by the
proximity of the Geer valley, which the more abrupt topography may not be well represented by
large finite elements. In particular, groundwater losses through the northern catchment boundary
may be variable along this border, while they are simulated in the model using a uniform 'head
dependent flux' boundary condition. This bias is then more representative of inadequacies in the
conceptual assumptions than in the calibration procedure. Although this kind of model errors
could have non negligible implications on model predictions, they are in this case quite limited
and local, as discussed later in Section 5.3, regarding the results of the sensitivity analysis.
Finally, Hill and Tiedeman (2007) propose to evaluate the 'Calculated error variance' or
'Calculated standard error' using Equation 5.2, as a measure of the overall model fit. If the
weighting scheme described above is used, a 'calculated standard error' equal to 1 means that the
model errors or residuals are consistent with the observation measurement errors. In other
words, it means that, in average, the model errors will be equivalent to the observation
measurement errors. For the Geer basin model, the 'calculated standard error' is equal to 10.2
with a 95% confidence interval between 9.9 and 10.55. This value indicates that, in average, the
model errors are greater than the measurement errors, which is common with hydrological
models. A 'calculated standard error' higher than 1 is not an indicator of badly construct models
with regard to the conceptual assumptions, but have some implications on the accuracy of the
predictions made with the calibrated model. The evaluation of the uncertainty related to the
model predictions is the subject of Section 8.2.
5 This confidence interval is calculated as suggested in Hill and Tiedeman (2007): 2
2
2
2
;LU
snsnχχ××
, where n is the
degree of freedom equal to the difference between the number of observation and the number of parameter, s is the 'calculated standard error', 2
Uχ and 2Lχ are the upper and lower tail value of a chi-square distribution with n degree
of freedom.
5. Modelling
84
Calculated error variance : ( )[ ]
( )NParNObs
byyws
NObs
iiii
−
−=∑ 2
2'
(5.2a)
Calculated standard error : ( )[ ]
( )
21
2'
⎟⎟⎟⎟
⎠
⎞
⎜⎜⎜⎜
⎝
⎛
−
−=∑
NParNObs
byyws
NObs
iiii
(5.2b)
NObs : Number of observations
NPar : Number of parameters
While the method exposed above enables to evaluate the overall fit of the model, the graphs of
Figure 5.5 and Figure 5.6 enable to evaluate the calibration in a 'transient' context. Figure 5.5
shows that groundwater seasonal variations, as calculated by the model, are slightly too high at
some observation wells, especially for ‘VIE044’, where the groundwater level is close to the
ground surface. However, simulated heads satisfactorily reproduce the multi-annual variations in
groundwater levels, which is important is the context of long term climate change impact on
groundwater reserves. These multi-annual variations are better reproduced in the upstream part
of the catchment (VIE044, BOR009, CEL167) than in the downstream part (SLI006, WIH014),
where they are overestimated. The observations are however more limited at WHI014 and
SLI006 which makes the evaluation of the calibration more hazardous. At Figure 5.6, the
simulated flow rates at the outlet of the basin are of the same order of magnitude as the observed
flow rates at the 'Kanne' gauging station. However, some discharge peaks present too high values
in comparison to the observed flow rates, and the associated recession periods are often too long.
This is especially noticed for high water discharge months (e.g. Figure 5.6C) for which these too
high and too long peaks result in overestimated monthly flow rates. Representative examples are
for December 1981, February 1984 and March 1988 when simulated flow rates are more than
twice as important as observed flow rates. Though it could not explain alone such a difference, it
5. Modelling
85
must be noted that the observed high water flow rates are characterised by a higher measurement
uncertainty given the lack of validation gauging for occasional high discharge events.
Nevertheless, simulated annual flow rates match quite well the observed annual flow rates and
the water balance analysis shows that the model overestimates by 0.3% of the total precipitation
the water flow rates at the 'Kanne' gauging station over the period 1975-2003. Table 5.7 shows
the main components of the water budget for the simulation performed between 1967 and 2003.
Figure 5.5 : Transient calibration of hydraulic heads for the nine observation wells
5. Modelling
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Figure 5.6. Transient calibration of surface flow rates for the Kanne gauging station (outlet)
5. Modelling
87
Rain Actual evapotransp.
North boundary
Outlet (‘Kanne’)
Water abstraction
Water balance error (∆ res.)
mm/year 803.5 -558.4 -45.0 -159.1 -51.4 -10.4
% of rainfall 100 -69.5 -5.6 -19.8 -6.4 -1.3
Table 5.7. Simulated mean water balance terms for the period 1967-2003
5.2 Sensitivity Analysis
At the same time as the calibration procedure, a sensitivity analysis for all parameters used in the
model was performed. When implementing and calibrating a model, performing a sensitivity
analysis is fundamental as it enables to identify which parameters are sensitive to the variables of
interest. Thanks to these results, the insensitive or nearly insensitive parameters can be ignored in
the calibration procedure as any change in their value will have very little effect on the variables
used in the analysis. This enables to drastically reduce computing times dedicated for calibration,
especially when automatic calibration codes are used. Here, the sensitivity analysis has been
performed using 'UCODE_2005' (Hill and Tiedeman, 2007; Poeter et al., 2005) in combination
with 'HydroGeoSphere'. UCODE_2005 is a computer code, developed by the 'U.S. Geological
Survey' (USGS), which can be coupled with other modelling codes to perform sensitivity analysis,
data needs assessment, calibration, prediction and uncertainty analysis. The sensitivity analysis of
the Geer basin model parameters (Figure 5.7) has been performed using the 'perturbation
method', which consists in perturbing one parameter by a small value – the others being kept
constant - and looking the effect on selected variables. UCODE_2005 is used to perturb each
parameter one by one, and to run one HydroGeoSphere simulation for each perturbed
parameter. The 'Composite Scaled Sensitivity' is then calculated for each parameter using
Equation 5.3 (Hill and Tiedeman, 2007) and the as weighting scheme described in Section 5.1.5.2
5. Modelling
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and Equation 5.1. The 'Composite Scaled Sensitivity' (CSS) aggregates the sensitivities of all
selected variables relatively to one parameter.
21
2.
2/1
⎟⎟⎟⎟⎟⎟
⎠
⎞
⎜⎜⎜⎜⎜⎜
⎝
⎛
⎟⎟⎠
⎞⎜⎜⎝
⎛××
∂∂
=∑
NObs
wbby
CSS
NObs
iij
j
i
j (5.3)
jCSS : Composite Scaled Sensitivity of parameter j
For the Geer basin model, selected variables correspond to monthly mean hydraulic heads at the
8 observation points and monthly mean flow rates at the outlet of the basin (Figure 4.1). In order
to limit computing times, the sensitivity of some similar parameters but for different zones are
calculated jointly by the means of unity multipliers. UCODE_2005 perturbs each multiplier that
acts simultaneously on several parameters, rather then to perturb all the parameters one by one in
different iterations. For the case of the Geer basin, the parameters sensitivities are generally
calculated jointly for all zones of the model. The hydraulic conductivity sensibilities are calculated
for each zone of Figure 5.2 independently of the layer and for each layer independently of the
horizontal zonation. As an example, the parameter related to the hydraulic conductivity of the
'dry valleys' in the 'upper chalk' layer is calculated using two different multipliers as shown in
Equation 5.4.
smMULTMULTK valleysDryChalkK
ChalkUpperK
ChalkUppervalleysDryChalk /102 4___
_−−
− ×××= (5.4)
As shown in Figure 5.7, the most sensitive parameters are the hydraulic conductivity of the 'dry
valleys', the field capacity used to calculate the actual evapotranspiration, the hydraulic
conductivity of the zones 'Chalk 1' (Figure 5.2), the hydraulic conductivities in the upper chalk
layer and the total porosity of the chalk. The hydraulic conductivity of the loess, parameters C2
5. Modelling
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and C1 used to calculate the transpiration, the conductance used in the Cauchy condition along
the North boundary, the hydraulic conductivity of the zone 'Chalk 5' located besides the outlet of
the catchment, the 'Leaf Area Index' and the wilting point present medium sensitivities to
observations. The other parameters show low sensitivities to observations. The specific storage
parameter has a very low sensitivity, in accordance with the fact that the aquifer is unconfined
over most of the catchment. The sensitivity of the Van Genuchten parameters could not be
calculated using 'UCODE_2005' because unsaturated functions are directly specified using tables
of values (Pressure – Relative hydraulic conductivity – Saturation) instead of the parameter
values. This constitutes a limitation of 'UCODE_2005'. However, the experience gained during
the calibration of the model showed that the parameters α and β (Table 5.2) also present a
significant sensitivity.
Figure 5.7. Composite Scales Sensitivities (CSS) of the parameters used in the Geer basin model
The same kind of analysis has been performed inversely, by aggregating the sensitivities of all
parameters relatively to one observation point (Equation 5.5). This aggregated value traduces the
relative importance of the information provided by each observation point in the calibration of
the parameters. Figure 5.8A presents the aggregated sensitivities for each of the 8 observation
5. Modelling
90
wells and for the 'Kanne' gauging station at the outlet of the catchment. Though all statistics have
more or less the same order of magnitude, this graphs shows that the simulated data at 'Kanne'
and A7-PL37 are the least sensitive to the parameters variations.
21
.2
.2/1
..
⎟⎟⎟⎟⎟⎟
⎠
⎞
⎜⎜⎜⎜⎜⎜
⎝
⎛
⎟⎟⎠
⎞⎜⎜⎝
⎛××
∂∂
=∑ ∑
NParNObs
wbby
CSS K
NObs
i
NPar
jij
j
i
K
K
(5.5)
KCSS : Composite Scaled Sensitivity for all observations of the observation point K
KNObs : Number of transient observations for observation point K
As proposed by Hill and Tiedeman (2007), the statistics of Figure 5.7 and Figure 5.8A can be put
in parallel with the 'leverage' statistics shown at Figure 5.8B. The 'leverage' statistic jointly
expresses the importance of an observation relatively to its parameters sensitivity and relatively to
its capability to reduce parameter correlations. In groundwater models, typical correlations occur
between recharge and hydraulic conductivity for which simultaneous inverse variations may have
little effects on groundwater levels. More details about the calculation of the 'leverage' statistic
can be found in Hill and Tiedeman (2007). For the Geer basin model, the flow rates at 'Kanne'
have the highest 'leverage', three times more important than the other observation points. Given
the relatively low aggregated sensitivity of the flow rates (Figure 5.8A), this high 'leverage' values
then traduces the capability of these observations to reduce the correlations between parameters
of the Geer basin model, when used in the calibration procedure. This analysis reinforces the
importance of using flow rate observations when calibrating the model, and demonstrates the
attractiveness of integrated surface – subsurface models.
5. Modelling
91
Figure 5.8. (A) Aggregated sensitivities for each observation point. (B) Mean leverage statistics for each
observation point.
5.3 Discussion
The modelling approach integrating surface flow, subsurface flow and evapotranspiration better
represents the interdependent aspect of recharge processes between surface and subsurface
domains compared to classical or externally coupled models, which is a key element in the
context of assessing potential climate change impacts on groundwater.
Spatial and temporal discretisations have been chosen to allow the study of long-term variations
of groundwater levels and water balance terms under changing climate. A 30-year simulation with
the Geer basin model using daily input data takes more than 12 days on a 3.0 GHz Pentium4
desktop machine equipped with 4 Gb RAM. Using a discretisation as fine as reported by Jones
(2005) and Li et al. (2008) (see Section 2), would lead to excessively large simulation times, mostly
5. Modelling
92
because of the much longer period covered by the climate change scenarios. However, the
objective of the model is not to simulate surface water at the river bed scale, but to provide an
accurate representation of the components of water balance at any time during the simulation.
Using a model with a coarser discretisation is assumed to be appropriate to study climate change
impacts while keeping the computational demand low. The grid used was developed according to
this objective.
Even with a limited number of nodes, computational times remain very large and make the
completion of an automatic calibration dramatically long. Automatic calibration or inversion
procedures minimize the objective function through several iterations, each of them including a
complete sensitivity analysis of all parameters. This implies running dozens of simulations and
leads to computing times as large as several years. The calibration performed here was then
performed by trial-an-error and, as all other calibrations, remains imperfect as shown in Section
5.1.5.2. Remaining uncertainty may translate into the results of climate change impact studies and
needs to be addressed. This is the subject of Section 8, where some 'UCODE_2005' capabilities
are used to calculate confidence intervals for predicted variables. Additionally to the uncertainty
around simulated values, the evaluation of the calibration performed at Section 5.1.5.2 also
showed a non negligible bias for simulated groundwater levels at A7-PL37, probably induced by
the North boundary condition which could be non adequate close to this observation well.
Although this kind of biases could have implications on subsequent prediction analysis, the
results of the sensitivity analysis show that they should be in this case quite limited. Simulated
values at A7-PL37 are the least sensitive to parameters and using observations at this well do not
play an important role in the reduction of parameters correlation (see Figure 5.8). It is then
expected that the effect of the bias at A7-PL37 will only have a local influence on subsequent
prediction analysis and will not spread elsewhere in the model. Results at A7-PL37 should
however be considered with caution. Finally, it must be noted that the calibration performed with
5. Modelling
93
the Geer basin model is original as it is performed using both observed hydraulic heads and
surface water flow rates. Most studies where fully integrated surface – subsurface hydrological
models are used do not present any calibration results for observed subsurface hydraulic heads
(Jones, 2005; Li et al., 2008; Sudicky et al., 2008). Van Roosmalen et al. (2007) only use one
observation per well to calibrate their model. Additionally, they only present global performance
criteria values aggregating hydraulic head error from all observation wells. Consequently, it is
impossible to evaluate the quality of the calibration regarding spatial and temporal variations.
Complete sensitivity analyses, as presented at Section 5.2, are usually performed in the context of
model automatic calibrations. They are also very useful even with more classic calibrations as the
sensitivity analysis helps the modeller to better understand the system and eliminate insensitive
parameters. It should be noted that the sensitivity results depend on parameters values because
the hydrological model is actually non-linear. As a consequence, a parameter which appears to be
nearly insensitive under specific conditions, might gain in importance under different conditions.
In the case of the Geer basin model, the 'leverage' statistics clearly show the role of the surface
flow rates observations in reducing parameters correlations. With a simple subsurface model,
high groundwater levels could be explained by low hydraulic conductivities, high recharge rates
or low discharge rates. The use of an integrated surface-subsurface hydrological model and the
analysis of all water balance terms then enable to better identify the origin of errors provided by
the model simulations. This better understanding gives some reliability to the interpretations,
reinforces the importance of using both flow rates and groundwater level observations when
calibrating the model and, more generally, gives some credibility to the methodology of using
surface-subsurface integrated models.
5. Modelling
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5.4 Alternative calibration
The results presented in Section 5.1.5 and the associated discussion showed that the calibration
of the Geer basin model is not perfect. As already said here above, large computing times and the
impossibility to use automatic calibration codes is one of the most important difficulties to be
faced when calibrating such catchment scale integrated models. Rather than spending huge time
quantities to achieve a better calibration, an alternative is to use several models with different
calibration results or different hypothesis in the conceptual model (Hill and Tiedeman, 2007).
While an – hopefully – better calibrated model may give more accurate prediction results, using
several different models will give a range of variation for predictions. This range of variation
traduces the uncertainty linked to the use of a model, and is sometimes more demanded by water
managers than a unique but more accurate prediction value. Following this idea, a second
calibrated model of the Geer basin is presented here after, and will be used in the following
chapters for the climate change impact study. Clearly, two models are not sufficient to evaluate
the uncertainty link to the use of hydrological models, but they will give a first idea about the
possible range of variation of climate change impacts.
This second model was developed previously to the first one and, in order to limit computational
time, specified fluxes were input on a monthly basis, using mean monthly precipitation,
evapotranspiration and groundwater abstraction rates. Adaptive time steps commonly vary
between 1 h and 1 day and a 30-year simulation takes a bit more than 1 day on a 3.0 GHz
Pentium4 desktop machine equipped with 4 Gb RAM. Figure 5.9, Figure 5.10 and Figure 5.11
present the calibration results for hydraulic heads and surface water flow rates. Generally,
computed heads are higher than observed heads, except in A7-PL37. Seasonal variations are still
too high and multi-annual variations in groundwater levels are underestimated at some
observation points. The simulated flow rates match well to observed values in summer, for low
flow rates and recession periods. Differences remain for all winter months, where simulated flow
5. Modelling
95
rates are too high. Over the period 1967-2003, simulated water flow rates at the 'Kanne' gauging
station overestimate by 6% of the total precipitation the observed flow rates. This overestimation
also implies that other water balance terms – actual evapotranspiration and water flux through
the North boundary – are underestimated. This model then presents important positive biases in
weighted residuals for the flow rates at the outlet of the aquifer and for all observation wells,
except for A7-PL37 which presents a negative bias. These biases have some implications on the
accuracy of the simulation results and make hazardous the evaluation of model uncertainty (Hill
and Tiedeman, 2007), as performed in Section 8 for the first hydrological model. Further
discussion about the use of this model is provided in Section 6. More details about the calibration
of this second model can be found in Goderniaux et al. (2009) and in Annex 1.
Figure 5.9. Transient calibration of hydraulic heads for the 8 observation wells (2nd model)
Figure 5.10. Transient calibration of surface flow rates for the Kanne gauging station (2nd model)
5. Modelling
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Figure 5.11. Graphical analysis of the model calibration. (A) Computed values vs. observed values. (B)
Residuals vs. observed values. (C) Weighted residuals vs. observed values.
5. Modelling
97
5.5 References
Asner, G.P., Scurlock, J.M.O. and Hicke, J.A., 2003. Global synthesis of leaf area index observations: implications for ecological and remote sensing studies. Global Ecology & Biogeography, 12(3): 191-205.
Breuer, L., Eckhardt, K. and Frede, H.-G., 2003. Plant parameter values for models in temperate climates. Ecological Modelling, 169: 237-293.
Brouyère, S., 2001. Etude et modélisation du transport et du piégeage des solutés en milieu souterrain variablement saturé (Study and modelling of transport and retardation of solutes in variably saturated media). PhD Thesis, University of Liège, Liège (Belgium), 640 pp.
Brouyère, S., Dassargues, A. and Hallet, V., 2004. Migration of contaminants through the unsaturated zone overlying the Hesbaye chalky aquifer in Belgium: a field investigation. Journal of Contaminant Hydrology, 72(1-4): 135-164.
Canadell, J., Jackson, R.B., Ehrlinger, J.R., Mooney, H.A., O.E., S. and Schulze, E.D., 1996. Maximum rooting depth of vegetation types at the global scale. Oecologia, 108: 583-595.
Dassargues, A. and Monjoie, A., 1993. The chalk in Belgium. In: R.A. Downing, M. Price and G.P. Jones (Editors), The hydrogeology of the chalk of the North-West Europe. Oxford University Press, Oxford, UK, pp. Chapter 8: 153 - 269.
Goderniaux, P., Brouyère, S., Fowler, H.J., Blenkinsop, S., Therrien, R., Orban, P. and Dassargues, A., 2009. Large scale surface - subsurface hydrological model to assess climate change impacts on groundwater reserves. Journal of Hydrology, 373(1-2): 122-138.
Hallet, V., 1998. Etude de la contamination de la nappe aquifère de Hesbaye par les nitrates: hydrogéologie, hydrochimie et modélisation mathématique des écoulements et du transport en milieu saturé (Contamination of the Hesbaye aquifer by nitrates: hydrogeology, hydrochemistry and mathematical modeling). PhD Thesis, University of Liège, Liège (Belgium), 361 pp.
Hill, M.C. and Tiedeman, C.R., 2007. Effective groundwater model calibration. With Analysis of data, sensitivities, predictions and uncertainty. John Wiley & Sons, New Jersey, 455 pp.
Hornberger, M.G., Raffensperger, J.P., Wilberg, P.L. and Eshleman, K.L., 1998. Elements of Physical Hydrology. JUH Press, 312 pp.
Jones, J.-P., 2005. Simulating Hydrologic Systems Using a Physically-based Surface-Subsurface Model: Issues Concerning Flow, Transport and Parameterization. PhD Thesis, University of Waterloo, Waterloo (Canada), 145 pp.
Kristensen, K.J. and Jensen, S.E., 1975. A Model For Estimating Actual Evapotranspiration From Potential Evapotranspiration. Nordic Hydrology, 6: 170-188.
5. Modelling
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Li, Q., Unger, A.J.A., Sudicky, E.A., Kassenaar, D., Wexler, E.J. and Shikaze, S., 2008. Simulating the multi-seasonal response of a large-scale watershed with a 3D physically-based hydrologic model. Journal of Hydrology, 357(3-4): 317-336.
Orban, P., Batlle-Aguilar, J., Goderniaux, P., Dassargues, A. and Brouyère, S., 2006. Description of hydrogeological conditions in the Geer sub-catchment and synthesis of available data for groundwater modelling. Deliverable R3.16, AquaTerra (Integrated Project FP6 no 505428).
Poeter, E.P., Hill, M.C., Banta, E.R., Mehl, S. and Christensen, S., 2005. UCODE_2005 and Six Other Computer Codes for Universal Sensitivity Analysis, Calibration, and Uncertainty Evaluation: U.S. Geological Survey Techniques and Methods 6-A11, 283 pp.
Scurlock, J.M.O., Asner, G.P. and Gower, S.T., 2001. Worldwide Historical Estimates of Leaf Area Index, 1932-2000, prepared for the Oak Ridge National Laboratory. ORNL/TM-2001/268, Oak Ridge, Tennessee.
Sudicky, E.A., Jones, J.-P., Park, Y.-J., Brookfield, E.A. and Colautti, D., 2008. Simulating complex flow and transport dynamics in an integrated surface-subsurface modeling framework. Geosciences Journal, 12(2): 107-122.
Therrien, R., McLaren, R.G., Sudicky, E.A. and Panday, S.M., 2005. HydroGeoSphere. A three-dimensional numerical model describing fully-integrated subsurface and surface flow and solute transport, 343 pp.
Van Roosmalen, L., Christensen, B.S.B. and Sonnenborg, T.O., 2007. Regional Differences in Climate Change Impacts on Groundwater and Stream Discharge in Denmark. Vadose Zone J, 6(3): 554-571.
Vázquez, R.F. and Feyen, J., 2003. Effect of potential evapotranspiration estimates on effective parameters and performance of the MIKE SHE-code applied to a medium-size catchment. Journal of Hydrology, 270(3-4): 309-327.
6. Application of climate change scenarios on the Geer basin model
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6. APPLICATION OF CLIMATE CHANGE SCENARIOS
ON THE GEER BASIN MODEL
6. Application of climate change scenarios on the Geer basin model
100
6. Application of climate change scenarios on the Geer basin model
101
As stated previously, the integrated Geer basin model has been specially developed to assess the
possible impacts of climate change on groundwater resources. As a next step climate change
scenarios are therefore applied to the basin model and projected changes and uncertainties are
assessed. Here, 6 climate change scenarios for 3 different time periods (2011-2040, 2041-2070,
2070-2100) are downscaled from Regional Climate Models (RCMs) to the station scale using a
'quantile mapping bias-correction' technique.
6.1 Climate scenarios
In order to assess the likely impacts of climate change on water resources for the Geer
catchment, Regional Climate Model (RCM) output from the European Union Fifth Framework
Programme (FP5) PRUDENCE project (Prediction of Regional scenarios and Uncertainties for
Defining EuropeaN Climate change risks and Effects) (Christensen et al., 2007) was used. These
dynamic climate models provide a series of high-resolution simulations of European climate for a
control simulation (1961-1990) and for a future time period (2071-2100). These are the results of
a series of “time-slice” experiments, each representing a stationary climate over the selected 30-
year period, whereby a climate model is allowed to fully adjust to an equilibrium state in response
to a prescribed radiative forcing, i.e. the simulations reflect variability about an equilibrium state
over a 30-year period. In addition to the uncertainty introduced by the choice of RCM, each
model derives its boundary conditions from a different GCM, with each GCM representing
atmospheric processes differently, either through different numerical schemes or different
parameterisations. One way of addressing these uncertainties is through the use of multi-model
ensembles. Here, we use an ensemble of 6 RCM simulations (Table 6.1) with boundary
conditions derived from what may be considered as two different GCMs, the HadAM3H
atmosphere only model (Gordon et al., 2000; Pope et al., 2000) and the ECHAM4/OPYC
coupled atmosphere-ocean model (Roeckner et al., 1996). The HadRM3P and ARPEGE RCM
simulations derive boundary conditions from HadAM3P and the coupled atmosphere-ocean
6. Application of climate change scenarios on the Geer basin model
102
model HadCM3 respectively. Both HadAM3H and HadAM3P are dynamically downscaled to an
intermediate resolution from the HadCM3 coupled atmosphere-ocean model and are thus closely
related. Further details on the RCMs used within PRUDENCE may be found in Jacob et al.
(2007).
Here, only projections using the SRES A2 emissions (medium-high) scenario (Nakicenovic et al.,
2000) are examined as recent observed increases in atmospheric carbon dioxide concentrations
are in accordance with projections from high emissions scenarios (Rahmstorf et al., 2007).
However, significant divergence in greenhouse gas concentrations between scenarios in the
second half of the 21st century generates uncertainty in future climate forcing. Although this
uncertainty arising from future emissions is not examined here it is discussed within the context
of the final results in Section 6.5. For each RCM, mean daily temperature and daily total
precipitation were extracted for the control and future time periods for the RCM grid cells
overlying the meteorological stations shown in Figure 4.1.
A2 SCENARIO
INST RCM GCM PRUDENCE ACRONYM
AQUATERRA ACRONYM
DMI HIRHAM HadAM3H A2 HS1 HIRHAM_H
DMI HIRHAM ECHAM4/OPYCA2 ecscA2 HIRHAM_E
HC HadRM3P HadAM3P A2 adhfa HAD_P_H
SMHI RCAO HadAM3H A2 HCA2 RCAO_H
SMHI RCAO ECHAM4/OPYCA2 MPIA2 RCAO_E
Météo-France Arpège HadCM3 A2 DE6 ARPEGE_H
Table 6.1. Climate change scenarios with corresponding RCM and GCM. DMI: Danish Meteorological Institute, HC: Hadley Center for Climate Prediction and Research, SMHI: Swedish Meteorological and
Hydrological Institute.
6. Application of climate change scenarios on the Geer basin model
103
6.2 Downscaling of RCM output
Even the relatively high-resolution RCMs (approximately 0.5° grids) used in this study are
too coarse to be effectively applied in hydrological impacts studies and a further downscaling step
is therefore required. One of the simplest downscaling methods that has been applied in
hydrological impacts assessment is the bias-correction approach (e.g. Fowler and Kilsby, 2007;
Kleinn et al., 2005). In this approach, biases in climate model control simulations of the mean
monthly climatology for the relevant grid cell relative to station observations are calculated
(calculated as a simple difference for temperature and a ratio for precipitation). This bias is
assumed to be the same for the future simulations and so corrected climate change scenarios may
therefore be obtained by applying the same bias corrections additively to daily temperature and as
a scalar to daily precipitation values for future time periods. However, this method only applies
the correction to the mean and does not take account of model deficiencies in reproducing
observed variability. We therefore adopt the quantile-based mapping approach to bias correction
described by Wood et al. (2004) which has been previously used in hydrological impacts studies
(e.g. Salathé et al., 2007). This mapping approach uses an empirical transfer function (e.g.
Panofsky and Brier, 1968) to force the probability distributions of the control simulations of daily
temperature and precipitation to match the observed distributions. Separate mapping functions
are calculated on a monthly basis for each station using the appropriate grid cell from each
model. Thus, for each RCM, the distributions of daily temperature and precipitation for the
control simulation are corrected to match those of the observed data, and are identical for each
model. Under the assumption that model biases are stationary in time, the same transfer
functions are therefore applied to adjust the temperature and precipitation scenarios for the
2071-2100 time period.
For many hydrologists and water resource planners, scenarios for the end of the 21st century do
not adequately reflect the most appropriate timescales for decision-making and planning. More
6. Application of climate change scenarios on the Geer basin model
104
frequently management decisions are made for the near-future, on decadal rather than century
timescales. To address these needs, scenarios were also produced for two additional time
periods: 2011-2040 and 2041-2070. To produce these we adopted a conventional pattern scaling
approach (Mitchell, 2003; Santer et al., 1990), assuming that changes to mean climate parameters
will occur in proportion to the projected change in global mean temperature. This method has
been used to construct climate change scenarios for hydrological impact studies (e.g. Salathé,
2005) and has been applied to the scaling of changes in different climatic variables for different
geographic regions and time periods (e.g. Mitchell et al., 1999; Santer et al., 1994; Tebaldi et al.,
2004). The changes in mean monthly temperature and total monthly precipitation were therefore
scaled for the relevant time periods in proportion to the mean global temperature change
projected by the GCM which provided lateral boundary conditions for each RCM simulation
(either HadCM3 or ECHAM4) using data available from the IPCC data distribution centre6.
6.3 Projected changes in local climate
The climate change scenarios for the 2071-2100 time period show a general increase in
temperature throughout the year (Figure 6.1A). The annual mean temperature increase for
Bierset ranges from +3.5°C (HIRHAM_H) to +5.6°C (RCAO_E) with the projected change
strongly influenced by the GCM used to drive the RCM simulations. Simulations driven by GCM
ECHAM4/OPYCA2 (scenarios HIRHAM_E and RCAO_E, see Table 6.1) project the greatest
increases, particularly during spring and summer. Although all models project the largest
temperature increases during summer with the maximum increases in August, those by
HIRHAM_E (~7.5°C) and RCAO_E (~9.5°C) are larger than those projected by the other
6 http://www.ipcc-data.org/
6. Application of climate change scenarios on the Geer basin model
105
models (+4.7°C to +6.4°C). All models project the smallest temperature increases during late
winter/early spring ranging from ~+2°C (HIRHAM_H; March) to ~+5.5°C (RCAO_E; March).
Figure 6.1. Monthly climatic changes for each climate change scenario (period 2071-2100) relatively to 1961-
1990. (A) Temperature - Bierset climatic station. (B) Precipitation - Waremme climatic station.
The RCMs consistently project a decrease in annual precipitation for the 2071-2100 time period
but there is a large range from −1.9 % (ARPEGE_H) to −15.3 % (HAD_P_H) (Figure 6.1B).
These precipitation decreases are a consequence of large projected decreases during summer
months but are partly offset by increases in winter precipitation. The largest summer decreases
are projected by RCAO_E but these are also offset by the largest winter increases projected by
6. Application of climate change scenarios on the Geer basin model
106
any of the models. The large annual decrease projected by HAD_P_H however arises as a
consequence of moderate decreases in summer precipitation that persist throughout autumn and
are only offset by comparatively small increases during winter.
Figure 6.2. Monthly climatic changes for the three time period 2011-2040, 2041-2070, 2071-2100 (climate model RCAO_E) relatively to 1961-1990. (A) Temperature – Bierset climatic station. (B) Precipitation –
Waremme climatic station.
Figure 6.2 shows monthly mean temperature and precipitation change for the three time periods
2011-2040, 2041-2070, 2071-2100 and for the climate model RCAO_E (GCM
ECHAM4/OPYCA2). In accordance with the pattern scaling approach used to downscale the
6. Application of climate change scenarios on the Geer basin model
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climate change scenarios, the temperature and precipitation change gradually increases from the
first time period to the third one, with a greater change between the second and third time
periods than between the first and second ones. Conclusions are similar for the climate models
driven by the other GCM (HadAM3).
All models therefore suggest that by the end of the century, the climate of the Geer basin will
consist of warmer, wetter winters and much hotter, drier summers, with a more pronounced
annual cycle of temperature and precipitation. Given the decreased summer rainfall, higher
evapotranspiration driven by higher temperatures and the projected regional increase in the
frequency of summer droughts (Blenkinsop and Fowler, 2007), increased stress is likely to be
placed on water resources during summer. During winter, higher evapotranspiration could be
offset by increased rainfall. The main form of uncertainty lies in the magnitude of the annual
groundwater recharge change and how quickly significant impacts on groundwater reserves will
be felt.
6.4 Projected changes in hydrological regime
Using the two calibrated flow models presented in Section 5 and the six downscaled RCM
scenarios, hydrological simulations were run to evaluate the direct climate change impacts on the
groundwater system of the Geer catchment for the three time periods 2011-2040, 2041-2070 and
2071-2100 using the bias-corrected precipitation and evapotranspiration scenarios. As the bias-
correction of each climate scenario reflects control simulation biases relative to observations,
future changes are expressed relative to an additional hydrological ‘control simulation’ driven by
the observed climate data. Daily PET are derived from temperature data using the Blaney-Criddle
method (Blaney and Criddle, 1950), which is a regression based approach that use relationships
between observed temperature and PET. Groundwater abstraction flow rates (from wells and
from the draining galleries) are firstly kept equal to zero through all simulations to avoid nodes
6. Application of climate change scenarios on the Geer basin model
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desaturation where abstraction flow rates are prescribed. The influence of groundwater
abstraction is discussed later in this section. As for the calibration procedure, initial conditions for
each time period and climate change scenario are obtained by running a preliminary steady state
simulation with the mean climatic data of the corresponding time period and climate change
scenario. Figure 6.3 and Figure 6.4 present the mean hydraulic head, the standard deviation,
minimum and maximum values for each time period, each RCM scenario and each observation
well. Similarly, Figure 6.5 and Figure 6.6 present the flow statistics at gauging station ‘Kanne’ for
each time period and each RCM scenario. These flow statistics are also presented for summer
and winter separately. Figure 6.3 and Figure 6.5 relate to climate change impact evaluated using
the hydrological model presented at Section 5.1.5 (calibration 1, with daily stresses). Figure 6.4
and Figure 6.6 relate to climate change impact calculated using the hydrological model presented
at Section 5.4 (calibration 2, with monthly stresses).
The results of the climate change impact study are quite different depending on the hydrological
model and calibration used. Using the first model, significant decreases are projected for almost
all groundwater levels and surface water flow rates, from the first to the third time period with a
gradual increase in intensity. By 2071-2100, mean groundwater levels are expected to decrease by
4-19 m depending on location in the Geer basin and the climate change scenario analysed (Figure
6.3). For an equivalent unsaturated zone depth, which smoothes recharge fluxes, the variability of
the groundwater levels is projected to increase. For the same period, flows at 'Kanne' are
expected to decrease by 37% - 65% depending on the climate change scenario, with a slightly
more important decrease during summer (Figure 6.5). Generally, the greatest changes are
projected by HAD_P_H which predicts large precipitation decreases during almost the whole
year, and by HIRHAM_E and RCAO_E which combine high increases in temperature and
medium decreases in precipitation. The smallest changes are projected by ARPEGE_H, which
combines a small increase in temperature with a small decrease in precipitation. The climate
6. Application of climate change scenarios on the Geer basin model
109
change impacts achieved when using the second hydrological model and calibration are
significantly less important. During 2011-2040, no clear change from the observed control
simulation can be identified, with large uncertainties projected in the direction of change for both
surface flow rate and mean groundwater hydraulic heads. By 2071-2100, mean groundwater levels
are expected to decrease by 2-7 m (Figure 6.4). Annual surface flow rates at 'Kanne' are expected
to decrease between 9% and 32%, with a more important decrease during summer and no
significant change during winter.
Table 6.2 and Table 6.3 present the changes in each of the water balance terms for each time
period and each RCM scenario. Table 6.2 and Table 6.3 relate to climate change impact calculated
using the two hydrological models presented at Section 5.1.5 (calibration 1) and 5.4 (calibration
2), respectively. Generally, both tables show a decrease in surface water flow rates at 'Kanne' (as
previously shown at Figure 6.5 and Figure 6.6), a decrease in water fluxes through the North
boundary, and an increase in actual evapotranspiration. Over the three time periods, the actual
evapotranspiration gains an increasing importance compared to the annual rainfall flux, which is
expected to decrease in the future. It results in a decreasing importance of the surface water flow
rates at 'Kanne' compared to annual rainfall. The main difference between both hydrological
models lies in the magnitude of the actual evapotranspiration change. The first hydrological
model enables large increases in relative and absolute actual evapotranspiration over the three
time periods. At equal rainfall and potential evapotranspiration rates, the second hydrological
model projects a lower increase in actual evapotranspiration relatively to the rainfall fluxes.
Moreover, the absolute actual evapotranspiration rates decrease, as the general increase in
temperature is offset by the decrease in water quantities available for evapotranspiration. This
analysis shows that the simulated actual evapotranspiration is strongly dependent on the
calibration of the models themselves. As already discussed in Section 2, the water quantities
6. Application of climate change scenarios on the Geer basin model
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available for evapotranspiration will indeed depend on how water circulates on the ground
surface, in the partially and fully saturated zones.
6.5 Discussion
The application of climate change scenarios as inputs of two hydrological models with different
calibrations leads to significantly different results. The differences are linked to the simulated
actual evapotranspiration rates which are more important with the first hydrological model.
According to the analysis performed in Section 5.4, the calibration of the second hydrological
model presents substantial biases in groundwater levels and surface water flow rates. Particularly,
the flow rates at the outlet of the catchment are significantly overestimated, due to an
underestimation of the actual evapotranspiration and/or water fluxes through the North
boundary. However, it is difficult to know which of these two terms is overestimated and in what
proportions. In view of these biases, the results of the impact study using the first hydrological
model should be considered as more reliable. Particularly, the first model offers the opportunity
to perform an uncertainty analysis (see Section 8), what would be hazardous with the second
model. Nevertheless, (though they have to be considered with caution,) the results from the
second model should not be rejected, as there is no indication that they are far from hypothetical
true predictions. Additionally, both models present imperfections regarding multi-annual
groundwater variations which are overestimated by the first model and underestimated by the
second one. Consequently, though more confidence is attached to the first hydrological model,
the impact study performed in this chapter gives a first range of variation linked to the calibration
of the hydrological models. A subsequent analysis concerning this kind of uncertainty is
presented at Section 8.
6. Application of climate change scenarios on the Geer basin model
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Figure 6.3. Evolution of hydraulic heads at the eight observation wells for each climate change scenario,
using the model with calibration 1.
6. Application of climate change scenarios on the Geer basin model
112
Figure 6.4. Evolution of hydraulic heads at the eight observation wells for each climate change scenario,
using the model with calibration 2.
6. Application of climate change scenarios on the Geer basin model
113
Figure 6.5. Evolution of flow rates at gauging station 'Kanne' for each climate change scenario, using the
model with calibration 1.
Figure 6.6. Evolution of flow rates at gauging station 'Kanne' for each climate change scenario, using the
model with calibration 2.
6. Application of climate change scenarios on the Geer basin model
114
Rain Actual
evapotransp.
Flux out of
North boundary
Flux out of
main outlet
(‘Kanne’)
Water
abstraction
mm/year 803.0 -498.8 -49.3 -254.0 0.0 Control period % of rainfall 100 -62.1 -6.1 -31.6 0.0
HIRHAM_H mm/year 774.6 -530.1 -47.8 -207.8 0.0
% of rainfall 100 -68.4 -6.2 -26.8 0.0
HIRHAM_E mm/year 776.9 -548.5 -46.9 -191.0 0.0
% of rainfall 100 -70.6 -6.0 -24.6 0.0
HAD_P_H mm/year 769.6 -532.8 -47.4 -199.5 0.0
% of rainfall 100 -69.2 -6.2 -25.9 0.0
RCAO_H mm/year 786.1 -533.3 -47.8 -215.0 0.0
% of rainfall 100 -67.8 -6.1 -27.4 0.0
RCAO_E mm/year 786.4 -553.0 -47.2 -199.7 0.0
% of rainfall 100 -70.3 -6.0 -25.4 0.0
ARPEGE_H mm/year 798.9 -532.5 -48.7 -239.1 0.0
2011
-204
0
% of rainfall 100 -65.5 -6.1 -29.9 0.0
HIRHAM_H mm/year 743.1 -559.1 -46.1 -154.5 0.0
% of rainfall 100 -75.2 -6.2 -20.8 0.0
HIRHAM_E mm/year 755.5 -576.9 -45.2 -146.7 0.0
% of rainfall 100 -76.4 -6.0 -19.4 0.0
HAD_P_H mm/year 733.0 -558.0 -45.3 -146.4 0.0
% of rainfall 100 -76.1 -6.2 -20.0 0.0
RCAO_H mm/year 767.4 -562.7 -46.5 -171.6 0.0
% of rainfall 100 -73.3 -6.1 -22.4 0.0
RCAO_E mm/year 772.6 -591.0 -45.4 -152.2 0.0
% of rainfall 100 -76.5 -5.9 -19.7 0.0
ARPEGE_H mm/year 794.7 -558.1 -47.6 -202.0 0.0
2041
-207
0
% of rainfall 100 -70.2 -6.0 -25.4 0.0
HIRHAM_H mm/year 697.9 -575.9 -43.0 -101.3 0.0
% of rainfall 100 -82.5 -6.2 -14.5 0.0
HIRHAM_E mm/year 719.1 -595.1 -42.4 -100.5 0.0
% of rainfall 100 -82.8 -5.9 -14.0 0.0
HAD_P_H mm/year 680.6 -563.8 -42.4 -99.7 0.0
% of rainfall 100 -82.8 -6.2 -14.7 0.0
RCAO_H mm/year 740.4 -590.6 -44.3 -123.3 0.0
% of rainfall 100 -79.8 -6.0 -16.7 0.0
RCAO_E mm/year 749.6 -618.8 -42.6 -107.2 0.0
% of rainfall 100 -82.6 -5.7 -14.3 0.0
ARPEGE_H mm/year 787.9 -592.4 -46.3 -164.2 0.0
2071
-210
0
% of rainfall 100 -75.2 -5.9 -20.8 0.0
Table 6.2. Variations of the mean water balance terms for each climate change scenario and time interval, using the model with calibration 1.
6. Application of climate change scenarios on the Geer basin model
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Rain Actual
evapotransp.
Flux out of
North boundary
Flux out of
main outlet
(‘Kanne’)
Water
abstraction
mm/year 803.0 -475.5 -40.9 -278.3 0.0 Control period % of rainfall 100 -59.2 -5.1 -34.7 0.0
HIRHAM_H mm/year 774.6 -462.7 -40.5 -266.7 0.0
% of rainfall 100 -59.7 -5.2 -34.4 0.0
HIRHAM_E Mm/year 776.9 -471.0 -40.1 -258.8 0.0
% of rainfall 100 -60.6 -5.2 -33.3 0.0
HAD_P_H Mm/year 769.6 -449.9 -40.5 -273.9 0.0
% of rainfall 100 -58.5 -5.3 -35.6 0.0
RCAO_H mm/year 786.1 -471.7 -40.5 -267.9 0.0
% of rainfall 100 -60.0 -5.1 -34.1 0.0
RCAO_E mm/year 786.4 -463.7 -40.4 -277.5 0.0
% of rainfall 100 -59.0 -5.1 -35.3 0.0
ARPEGE_H mm/year 798.9 -472.2 -40.9 -285.3 0.0
2011
-204
0
% of rainfall 100 -59.1 -5.1 -35.7 0.0
HIRHAM_H mm/year 743.1 -458.4 -39.8 -240.2 0.0
% of rainfall 100 -61.7 -5.4 -32.3 0.0
HIRHAM_E mm/year 755.5 -468.9 -39.5 -239.0 0.0
% of rainfall 100 -62.1 -5.2 -31.6 0.0
HAD_P_H mm/year 733.0 -450.7 -39.9 -237.6 0.0
% of rainfall 100 -61.5 -5.4 -32.4 0.0
RCAO_H mm/year 767.4 -470.7 -39.9 -250.0 0.0
% of rainfall 100 -61.3 -5.2 -32.6 0.0
RCAO_E mm/year 772.6 -465.7 -39.8 -260.7 0.0
% of rainfall 100 -60.3 -5.2 -33.7 0.0
ARPEGE_H mm/year 794.7 -485.9 -40.4 -266.7 0.0
2041
-207
0
% of rainfall 100 -61.1 -5.1 -33.6 0.0
HIRHAM_H mm/year 697.9 -436.7 -39.0 -216.8 0.0
% of rainfall 100 -62.6 -5.6 -31.1 0.0
HIRHAM_E mm/year 719.1 -449.5 -38.8 -221.7 0.0
% of rainfall 100 -62.5 -5.4 -30.8 0.0
HAD_P_H mm/year 680.6 -440.0 -39.0 -197.1 0.0
% of rainfall 100 -64.7 -5.7 -29.0 0.0
RCAO_H mm/year 740.4 -455.1 -39.3 -238.3 0.0
% of rainfall 100 -61.5 -5.3 -32.2 0.0
RCAO_E mm/year 749.6 -448.8 -39.1 -253.1 0.0
% of rainfall 100 -59.9 -5.2 -33.8 0.0
ARPEGE_H mm/year 787.9 -489.8 -39.9 -255.2 0.0
2071
-210
0
% of rainfall 100 -62.2 -5.1 -32.4 0.0
Table 6.3. Variations of the mean water balance terms for each climate change scenario and time interval, using the model with calibration 2.
6. Application of climate change scenarios on the Geer basin model
116
As stated in Section 6.1, adopting a multi-model approach for the climate scenarios enables the
uncertainty derived from climate model selection to be incorporated into the assessment of the
impacts of climate change on the Geer catchment. The full range of uncertainties in future
climate scenarios is not represented in this study, as only six regional climate models from the
larger PRUDENCE ensemble have been used. However, the same framework could readily be
applied to a larger ensemble size given adequate computational resources. Furthermore, the
uncertainty in future emissions is not addressed in this study. Whilst the PRUDENCE project
does provide some RCM simulations for the same future time period (2071-2100) for the B2
emissions (medium-low) scenario, the application of these to the groundwater model is unlikely
to provide a greater understanding of future uncertainties in the response of the Geer basin. A
comparison of the contribution of the various sources of uncertainty within the PRUDENCE
model simulations indicates that emission scenario is the most important source only for summer
temperatures over southern Europe (Déqué et al., 2007). Generally, the uncertainty introduced
by the GCM boundary conditions is larger than that for the other sources whilst the RCM
introduces uncertainty of a similar magnitude to that of the GCM boundary conditions only for
summer precipitation. Here, the full range of uncertainty generated by the choice of GCM
boundary conditions is necessarily constrained by the experimental combinations provided by the
PRUDENCE project and has been maximised in terms of the subset of experiments selected in
this analysis. However, it is evident that the limited GCM selection applied in PRUDENCE
constrains the uncertainty measured from this source (Déqué et al., 2007). It is noted that the A2
and B2 scenarios examined by PRUDENCE only constitute 50% of the spread of greenhouse
gas concentrations from all SRES scenarios (Déqué et al., 2007) and that impact studies using a
larger range of emission scenarios suggest a greater contribution to total uncertainty generated by
emissions relative to RCM choice (e.g. Olesen et al., 2007). Nonetheless, this study provides a
major advance in the assessment of the uncertainty of the impact of climate change on
groundwater systems.
6. Application of climate change scenarios on the Geer basin model
117
The impact study performed in this chapter does not consider any water abstraction though it
represents a non negligible water balance term for the period 1967-2003. Including some water
abstraction terms in the analysis will cause a decrease in absolute groundwater levels and surface
water flow rates, but the possible effect on groundwater drawdown linked to climate change is
less certain. To test the influence of pumping wells and draining galleries, additional climate
change simulations were performed, including groundwater abstraction flow rates. For different
reasons explained in Section 4, the draining galleries in the Geer basin can not be considered as
typical drains. Using a 'third type' (head dependant flux) boundary condition to represent them is
then not adequate, and they are actually represented with 'second type' (specified flux) boundary
condition in the model. The problem with this boundary condition is that the abstraction
volumes for the next decades are not known. The actual abstraction volumes for the period
1967-2003 show a relative correlation with the variations of the observed multi-annual
groundwater levels, but in the context of climate change, these groundwater levels are precisely
not known in advance. In this additional impact study, the abstraction flow rates have then been
fixed to the mean abstraction flow rates for the period 1967-2003 and are kept constant through
all simulations. The fact that the specified flow rates are constant constitutes a limitation because
the mean flow rate value may be too important in periods of low groundwater levels, inducing
node desaturation where negative flow rates are specified and the end of the simulation. To avoid
these numerical problems, the influence of groundwater abstraction on the climate change impact
has been tested using the second hydrological model, less prone to exhibit node desaturation.
Using this model also allows saving computing times. According to these new simulations,
groundwater levels, for the period 2071-2100 are expected to decrease by 2-8 m, instead of 2-7 m
when not considering water abstraction. The decrease is then slightly more important with active
wells and draining galleries, but the difference between both cases is small compared to the
difference achieved when using the two alternative calibrated models. Complete results
6. Application of climate change scenarios on the Geer basin model
118
concerning the simulations with groundwater abstraction can be found in Goderniaux et al.
(2009).
Finally, the influence of the temporal discretisation on the climate change impact results was also
examined. Using the first hydrological model, identical climate change simulations were
subsequently run, using mean daily and mean monthly specified fluxes (potential
evapotranspiration and precipitation). Results (not presented here) show very small differences
between both temporal discretisations regarding the climate change impact on groundwater levels
and surface water flow rates at the outlet of the aquifer. The influence of the temporal
discretisation of the specified fluxes is also examined and discussed in more details in the next
Section.
6. Application of climate change scenarios on the Geer basin model
119
6.6 References
Blaney, H.F. and Criddle, W.D., 1950. Determining water requirements in irrigated areas from climatological irrigation data. Technical Paper n°96, US Department of Agriculture, Soil Conservation Service, Washington, D.C.
Blenkinsop, S. and Fowler, H.J., 2007. Changes in European drought characteristics projected by the PRUDENCE regional climate models. International Journal of Climatology, 27: 1595-1610.
Christensen, J.H., Carter, T.R., Rummukainen, M. and Amanatidis, G., 2007. Evaluating the performance and utility of regional climate models: The PRUDENCE project. Climatic Change, 81(Supplement 1): 1-6.
Déqué, M. et al., 2007. An intercomparison of regional climate simulations for Europe: assessing uncertainties in model projections. Climatic Change, 81(0): 53-70.
Fowler, H. and Kilsby, C., 2007. Using regional climate model data to simulate historical and future river flows in northwest England. Climatic Change, 80(3): 337-367.
Goderniaux, P., Brouyère, S., Fowler, H.J., Blenkinsop, S., Therrien, R., Orban, P. and Dassargues, A., 2009. Large scale surface - subsurface hydrological model to assess climate change impacts on groundwater reserves. Journal of Hydrology, 373(1-2): 122-138.
Gordon, C., Cooper, C., Senior, C.A., Banks, H., Gregory, J.M., Johns, T.C., Mitchell, J.F.B. and Wood, R.A., 2000. The simulation of SST, sea ice extents and ocean heat transports in a version of the Hadley Centre coupled model without flux adjustments. Climate Dynamics, 16(2): 147-168.
Jacob, D. et al., 2007. An inter-comparison of regional climate models for Europe: model performance in present-day climate. Climatic Change, 81(Supplement 1): 31-52.
Kleinn, J., Frei, C., Gurts, J., Lüthi, D., Vidale, P.L. and Schär, C., 2005. Hydrologic simulations in the Rhine basin driven by a regional climate model. Journal of Geophysical Research, 110: 18.
Mitchell, J.F.B., Johns, T.C., Eagles, M., Ingram, W.J. and Davis, R.A., 1999. Towards the Construction of Climate Change Scenarios. Climatic Change, 41(3): 547-581.
Mitchell, T.D., 2003. Pattern Scaling: An Examination of the Accuracy of the Technique for Describing Future Climates. Climatic Change, 60(3): 217-242.
Nakicenovic, N. et al., 2000. Emissions Scenarios. A Special Report of Working Group III of the Intergovernmental Panel on Climate Change, Cambrigde University Press, Cambridge.
Olesen, J. et al., 2007. Uncertainties in projected impacts of climate change on European agriculture and terrestrial ecosystems based on scenarios from regional climate models. Climatic Change, 81(0): 123-143.
6. Application of climate change scenarios on the Geer basin model
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Panofsky, H.A. and Brier, G.W., 1968. Some applications of statistics to meteorology. The Pennsylvania State University, University Park, 224 pp.
Pope, V.D., Gallani, M.L., Rowntree, P.R. and Stratton, R.A., 2000. The impact of new physical parametrizations in the Hadley Centre climate model: HadAM3. Climate Dynamics, 16(2): 123-146.
Rahmstorf, S., Cazenave, A., Church, J.A., Hansen, J.E., Keeling, R.F., Parker, D.E. and Somerville, R.C.J., 2007. Recent Climate Observations Compared to Projections. Science, 316(5825): 709-709.
Roeckner, E. et al., 1996. The atmospheric general circulation model ECHAM-4: model description and simulation of present-day climate. Report n° 218, Max-Planck Institute for Meteorology, Hamburg, Germany.
Salathé, E.P., 2005. Downscaling simulations of future global climate with application to hydrologic modelling. International Journal of Climatology, 25(4): 419-436.
Salathé, E.P., Mote, P.W. and Wiley, M.W., 2007. Review of scenario selection and downscaling methods for the assessment of climate change impacts on hydrology in the United States pacific northwest. International Journal of Climatology, 27(12): 1611-1621.
Santer, B.D., Brüggemann, W., Cubasch, U., Hasselmann, K., Höck, H., Maier-Reimer, E. and Mikolajewica, U., 1994. Signal-to-noise analysis of time-dependent greenhouse warming experiments. Climate Dynamics, 9(6): 267-285.
Santer, B.D., Wigley, T.M.L., Schlesinger, M.E. and Mitchell, J.F.B., 1990. Developing climate scenarios from equilibrium GCM results. Rpt. No. 47, Max-Plandk-Institut-fur-Meteorologie, Hamburg (Germany).
Tebaldi, C., Nychka, D. and Mearns, L.O., 2004. From global mean responses to regional signals of climate change: simple pattern scaling, its limitations (or lack of) and the uncertainty in its results. Proceedings of the 18th Conference of Probability and Statistics in the Atmospheric Sciences, AMS Annual Meeting, Seattle (U.S.A.).
Wood, A.W., Leung, L.R., Sridhar, V. and Lettenmaier, D.P., 2004. Hydrologic Implications of Dynamical and Statistical Approaches to Downscaling Climate Model Outputs. Climatic Change, 62(1): 189-216.
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7. APPLICATION OF STOCHASTIC CLIMATE CHANGE
SCENARIOS ON THE GEER BASIN MODEL
7. Application of stochastic climate change scenarios on the Geer basin model
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7. Application of stochastic climate change scenarios on the Geer basin model
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7.1 Objectives
In Section 6, climate change scenarios downscaled using the 'Quantile Mapping Bias Correction'
technique were used to evaluate the impact of climate change on groundwater reserves in the
Geer basin. This technique presents however two important limitations. First, simulations are
performed for the three time slices 2011-2040, 2041-2070 and 2071-2100, with climatic time
series representing a stationary climate over each of these time slices. In reality, the change in
climatic conditions is expected to continuously increase over the years. Second, each RCM is
represented by a unique climatic time series for each time slice. However, while mean climatic
statistics can be projected in the future, it is not possible to predict the weather or the exact
values of climatic variables at a specific time in the future. In the context of a climate change
impact study, it implies that it is difficult to project groundwater levels at a specific date by using
only one climatic scenario. A given specific future year, simulated for example as a 'dry year' in a
climatic scenario, could indeed correspond to a 'dry year' in reality.
In this section, new developments are performed to overcome these two limitations. The
objectives of this additional analysis are twofold:
(1) to simulate groundwater flow conditions using climate change scenarios that simulate the
change of mean climatic statistics in a fully transient way;
(2) to evaluate the possible range of variation of projected flow conditions, due to the natural
variability of the weather around mean climatic statistics. The idea is to use a large
number of equiprobable climatic scenarios as input of the Geer basin model, and to
calculate possible impact on groundwater reserves in a probabilistic way.
To reach these objectives, a 'weather generator' is used to downscale and generate 100
equiprobable climatic time series representing continuously changing climatic conditions from
7. Application of stochastic climate change scenarios on the Geer basin model
124
2010 to 2085, for each of the 6 climate model used in Section 6 (see Table 6.1). Similarly to other
statistical downscaling techniques, the 'weather generator' is more accurate than RCMs and it
enables to generate climatic scenarios at the catchment scale, with limited computing resources.
Additionally, the 'weather generator' used in this study represents more realistically the weather
variability and climatic extremes, in comparison with the other statistical or dynamical
downscaling techniques. Finally, it enables to simulate data time series for all variables used in the
Penmann-Montheith equation and to calculate the related potential evapotranspiration time series
in a more direct and accurate way than with the Blaney-Criddle method used in Section 6. The
'weather generator' used in this study is part of the most advanced downscaling techniques, but it
has never been used in a climate change impact study on groundwater reserves.
Section 7.2 describes the functioning of the 'weather generator' downscaling technique used in
this study, and presents the climatic scenarios generated for the Geer basin. Section 7.3 analyses
the results of the application of all stochastic scenarios as input to the Geer basin hydrological
model. Section 7.4 examines what are the implications on the results when applying different
numbers of scenarios on the hydrological model, and when using different time discretisations.
Section 7.5 provides additional discussions.
7.2 Simulation of the stochastic climate change scenarios
For the Geer basin case study, 100 equiprobable climatic scenarios from 2010 to 2085 were
generated for each of the 6 Regional Climate Models (RCM) and for a control period without any
climate change. The generation of these climatic scenarios is performed in two main steps. First,
the daily precipitation time series from 2010 to 2085 are generated using the rainfall model
'RainSim' (Burton et al., 2010; Burton et al., 2008). Second, the precipitation time series generated
with 'RainSim' are used as input of the 'CRU daily weather generator' (Kilsby et al., 2007; Watts et
al., 2004) to produce associated data time series for the other variables (temperature max.,
7. Application of stochastic climate change scenarios on the Geer basin model
125
temperature min., relative humidity, sunshine hours, wind speed, atmospheric pressure). The
associated evapotranspiration time series are then calculated using the Penman-Montheith
equation.
Observed data used to calibrate 'RainSim' correspond to precipitation from Waremme climatic
station (1961-1990), which has been identified as the most representative across the Geer basin.
Observed data used to calibrate the 'CRU weather generator' (temperature, relative humidity,
sunshine hours, wind speed, vapour pressure, solar radiation) are from Bierset station (1961-
1990), where long continuous data time series are available. Except for 7 years of daily
temperature data, the additional variables required for the 'CRU weather generator' are not
available at Waremme station, from where precipitation data are used. However, Bierset and
Waremme climatic stations are located only 15 kilometres away. Daily precipitation data for both
stations present a very good correlation with slightly higher mean precipitations at Bierset. Daily
temperature data for the 7 common years present a quasi perfect correlation and differences in
mean monthly temperatures do not exceed 0.2°C.
The main concepts used by the 'RainSim' rainfall model and the 'CRU weather generator', as well
as results concerning the data time series generated for the Geer basin are presented in sections
7.2.1 and 7.2.2.
7.2.1 Generation of precipitations times series using 'RainSim'
RainSim is a stochastic rainfall generator that enables, among others, to perform statistical
downscaling of climate change scenarios and to generate large number of stochastic
precipitations time series. The concepts and equations used in RainSim are presented in Burton et
al. (2008) and Burton et al. (2010). These concepts are summarized here after.
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7.2.1.1 General concepts
RainSim is based on the Neyman-Scott rectangular pulses (NSRP) model (Cowpertwait, 1991;
Neyman and Scott, 1958) which conceptualises each rainfall event as the aggregation of several
"rain cells" (or rain rectangular pulses) characterised by a rainfall intensity and duration (Figure
7.1). The properties of all rainfall events and their associated "rain cells" are determined by
several random variables governed by specific statistical distributions and specified parameters.
All these random variables, their corresponding statistical distribution and parameters are
presented in Table 7.1. Figure 7.1 presents the main concepts of the NSRP model.
Figure 7.1. Schematic of the NSRP stochastic rainfall model (Figure from Burton et al., 2008). The circles
represent the rainfall events. Each star is associated with the beginning of a 'rain cell'.
7. Application of stochastic climate change scenarios on the Geer basin model
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Random variable Statistical distribution of the random variable
Parameter defining the statistical distribution
Time interval between rain events [T] Poisson λ
Number of "rain cells" for each rain event [-] Poisson ν
Time interval between the origin of each "rain cell" and the origin of the corresponding rain event [T] Exponential β
Intensity of each "rain cell" [LT-1] Exponential η
Duration of each "rain cell" [T] Exponential ξ
Table 7.1. Random variables used in the NSRP model
7.2.1.2 Calibration of the model for the control scenarios (without any climate
change)
Different rainfall time series can therefore be generated using the NSRP model given the
specification of the parameters defining the statistical distributions and different outcomes of the
random variables presented in Table 7.1. These parameters are usually calibrated by fitting the
NSRP model to observed data and a distinct calibration is usually performed for each month of
the calendar. More particularly, RainSim performs automatic calibration for each month of the
calendar by fitting specific statistics derived from simulated rainfall time series to the equivalent
statistics derived from observed time series. In this study, the following 6 observed rainfall
statistics are used to calibrate the model:
- daily mean
- daily variance
- monthly variance
- probability of a dry day (< 1 mm)
- daily lag-1 autocorrelation.
- daily skewness coefficient = ( )( )[ ]
3
3
dY
dd YEYEσ−
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Yd : Daily rain accumulation
2dYσ : Variance of the daily rain accumulation
The probability of a dry day is evaluated considering that a day is dry if rain accumulation is less
than 1 mm. The daily lag-1 autocorrelation is the cross correlation of the rainfall time series with
itself considering a time-lag of 1 day. The daily skewness coefficient in the calibration is
particularly important to get a good representation of extremes events.
Though it is automatically performed by 'RainSim', the user can control the calibration by
weighting each of these 6 statistics in the objective function and by specifying some upper and
lower bounds to the parameters. The set of weights is chosen to get the best fit of simulated to
observed statistics, in accordance with the objectives of the underlying study. As an example, in a
study where the representation of climate extremes is important (drought, floods), the user can
decide to increase the weight of the daily skewness coefficient.
Figure 7.2 presents observed, fitted and simulated statistics for the Geer basin climate
corresponding to the period 1961 – 1990. The black lines correspond to observed data. The black
crosses refer to the statistics as fitted by 'RainSim' after the calibration process. The red circles
refer to 10 different stochastic simulations for time intervals of 100 years under the same climate
conditions than the observation period 1961 – 1990. Generally, the resulting fit as obtained with
'RainSim' is good although deviations are noticed for the daily skewness coefficient and monthly
variance. The range of variation displayed by the 100-years stochastic simulations almost always
include the corresponding observed statistic value.
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Figure 7.2. Observed, fitted and simulated precipitation statistics for the Geer basin climate corresponding
to the period 1961 – 1990
7.2.1.3 Calibration of the model for the climate change scenarios
The parameters values achieved with this calibration (Figure 7.2) relate to the observed climatic
data of the period 1961 – 1990. In the context of climate change, where climatic statistics are by
definition expected to change, these parameter values can not be used and new parameter value
have to be calculated for any different "climatic state". More particularly, to simulate a continuous
and gradual change between 2010 and 2085, the parameter values should also vary continuously
7. Application of stochastic climate change scenarios on the Geer basin model
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with time and climate change intensity. In practical terms, new parameter values have to be
calculated for each year of the time period and for each month of the calendar. To generate
complete stochastic simulations between 2010 and 2085, it then implies the calculation of 912
different sets of 5 parameters (see Table 7.1).
'RainSim' can routinely calculate all these parameters based on "observed", or "target", climatic
statistics for all months and years between 2010 and 2085. These target climatic statistics can be
achieved, in two steps, thanks to data provided by RCMs and GCMs. First, the climatic statistics
for 2085 are calculated using the Geer basin observed climatic statistics for the period 1961 –
1990, and the statistics of a RCM 30-year time slices for the periods 1961 – 1990 (control period)
and 2071 – 2100 (Equation 7.1). Second, the climatic statistics for each year between 2010 and
2085 are interpolated considering that rainfall statistics vary in the same proportions as the
temperatures from the GCM used to drive the RCM boundary conditions. A scaling factor is
calculated according to Equation 7.2 for the years 2025 and 2055. The scaling factor of the years
1975 and 2085 is equal to 0 and 1, respectively. Between 1975, 2025, 2055 and 2085, the scaling
factor is interpolated linearly. Finally, the rainfall statistics are calculated according to Equation
7.3.
( ) 19901961,__,
_
21002071,_2086
_−
−
×= obsmonthiperiodcontrolRCM
monthi
RCMmonthi
monthi statstat
statRCMstat (7.1)
GCMperiodcontrol
GCM
GCMperiodcontrol
GCMyearGCM
year TTTT
SF_21002071
_
−−
=−
(7.2)
( ) ( )( )19901961_
2086_
19901961__
−− −×+= monthimonthiGCMyearmonthi
yearmonthi statRCMstatSFstatRCMstat (7.3)
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As an illustration, Figure 7.3 presents the scaling factor evolution between 1975 and 2085 for the
GCM 'ECHAM4/OPYCA2' which drives the boundary conditions of RCMs 'HIRHAM_E' and
'RCAO_E' (Table 6.1). According to this graph, the rate of change is expected to be more
important at the end of the 21st century. Figure 7.4 also shows the target climatic statistics of
'RCAO_E', which projects the largest change (Figure 6.1), for 4 years (1995, 2025, 2055 and
2085). As expected, the daily mean precipitations and the probability of a dry day increase during
winter and decrease during summer. The daily skewness coefficient, which is important to get a
good representation of extremes events, increases for almost all months. The variances and
autocorrelation have more unpredictable variations, depending on the month of the calendar.
More details can be found in (Burton et al., 2010; Burton et al., 2008).
Figure 7.3. Evolution of the scaling factors between 1975 and 2085 for GCM ECHAM4/OPYCA2
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Figure 7.4. Target climatic statistics of RCAO_E for years 1995, 2025, 2055, 2085
7. Application of stochastic climate change scenarios on the Geer basin model
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This procedure for calibrating the parameters and calculating the 'target' statistics between 2010
and 2085 was repeated for the 6 RCMs listed in Figure 6.1. To validate the calibration, target and
simulated mean climatic statistics have then been compared. For each year between 1975 and
2085, a 1000-year rainfall time series corresponding to a stationary climate equivalent to the
climatic conditions of the year, was generated using the related set of parameters. Mean statistics
were then calculated for each 1000-year time series, and compared to the corresponding target
statistics. Using 1000-years time series enables to calculate robust mean statistics, what is less
evident with shorter time periods. Some results of this comparison are presented at Figure 7.5 for
February and August of 'RCAO_E'. As shown on the graphs, the 'daily mean precipitation' and
'probability of a dry day' target statistics match closely the equivalent mean simulated statistics.
Conclusions are similar for the other statistics and calendar months.
Figure 7.5. Evolution of target and mean simulated statistics (for successive periods of 1000 years) between
1975 and 2085 for RCAO_E
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7.2.1.4 Generation of the climate change time series for the Geer basin
Following this validation, 100 equiprobable rainfall daily time series were then generated from
2010 to 2085 by 'RainSim' for each RCM, by using the successive sets of parameters for each year
and each calendar month. Figure 7.6 presents the stochastic climate change scenarios related to
ARPEGE_H and RCAO_E. For the sake of clarity, only 30 time series are plotted on each
graph. In accordance with Figure 6.1, precipitations increase during winter and decrease during
summer, with larger changes for RCAO_E than for ARPEGE_H.
Figure 7.6. Stochastic climate change scenarios. Precipitations of RCAO_E and ARPEGE_H for February
and August
7.2.2 Generation of PET time series using the 'CRU daily weather generator'
Once the precipitation time series have been generated, the second step in the production of the
climatic scenarios consists in the generation of the other variables using the 'CRU daily weather
generator'. The methodology for generating these variables is described in detail in Kilsby et al
(2007). The complete analysis for the Geer basin is presented in Blenkinsop et al. (2010).
7. Application of stochastic climate change scenarios on the Geer basin model
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7.2.2.1 General concepts
The method, which is summarised here after, is based on observed correlation and auto-
correlation relationships between climatic variables. Daily precipitation time series are generated
separately from the other variables because precipitation is conceptualised as a clustered rainfall
event, simulated using the more adequate 'Neyman-Scott rectangular pulses' model (see Section
7.2.1), and the other meteorological variables, considered as continuous phenomena, are more
easily simulated by regression procedures. Observed data for all variables, except precipitation,
are firstly normalised (zero mean and unit standard deviation of the statistical distribution). This
normalisation is performed separately for each half month of the calendar (12 × 2), and for four
different transition types between days ('wet-wet', dry-dry', 'wet-dry' and 'dry-wet') determined
depending on the wet/dry status of the preceding and current day. A regression relationship
similar to Equations 7.4 (Kilsby et al., 2007) is then calibrated for each variable and for each of
the 96 distributions (12 × 2 × 4).
111111 dPcPbTaT iiii +++= −−
221212 dPcPbRaR iiii +++= −−
jijijijijij eRdTcPbRaX ++++= −1 (7.4)
iT : Normalised daily temperature on day i
iP : Normalised daily precipitation on day i
iR : Normalised daily temperature range (TMAX- TMIN) on day i
ijX : Remaining normalised variables on day i (j=3, #variables)
jjjjj edcba ,,,, : Correlation and auto-correlation coefficients evaluated for each
variable and each regression
7. Application of stochastic climate change scenarios on the Geer basin model
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To generate new climatic data time series, these correlation and auto-correlation coefficients are
then used in Equations 7.5, where 'r' is a random normal variable scaled depending on each
regression. These equations have the advantage of preserving the correlation and auto-correlation
between all variables. Normalised new values are then scaled back to absolute values using the
corresponding means and standard deviations (Kilsby et al., 2007).
rdPcPbTaT iiii ++++= −− 111111
rdPcPbRaR iiii ++++= −− 221212
reRdTcPbRaX jijijijijij +++++= −1 (7.5)
To generate future climate change times series, all coefficients are kept constant but the means
and standard deviations used to scale back normalised values are adapted depending on the year.
The scaling scheme used here is similar to what is done for precipitation (see Figure 7.3 and
Section 7.2.1.3).
7.2.2.2 Generation of the climate change time series for the Geer basin
For the Geer basin case study, 100 time series from 2010 to 2085 were generated for each of the
6 climatic models of Table 6.1, and for a 'control period' without any climate change, similarly to
the case of precipitation. Simulated variables are the daily mean temperature, the daily
temperature range (TMAX – TMIN), the daily mean vapour pressure, the daily mean wind speed, the
daily sunshine hours, and the daily mean solar radiation. The potential evapotranspiration is
calculated using the Penman-Montheith equation. Figure 7.7 and Figure 7.8 show the
temperature and PET time series for February and August, related to the climatic models
ARPEGE_H and RCAO_E. These graphs are consistent with the general increase in
temperature and PET during the whole year, with larger increases for RCAO_E and during
summer months (Figure 6.1).
7. Application of stochastic climate change scenarios on the Geer basin model
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Figure 7.7. Stochastic climate change scenarios. Monthly mean temperature of RCAO_E and ARPEGE_H
for February and August
Figure 7.8. Stochastic climate change scenarios. Monthly mean PET of RCAO_E and ARPEGE_H for
February and August
7. Application of stochastic climate change scenarios on the Geer basin model
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7.3 Application of the climate change scenarios on the Geer basin model
7.3.1 Simulation conditions
One hundred equiprobable climate change scenarios (2010-2085) have been generated for each
of the 6 climatic models (RCM – GCM). To save computing times, which are very large for each
hydrological simulation, only 30 scenarios were firstly applied as input of the Geer basin
hydrological model (calibration 1 with daily stresses, see Section 5). 30 additional scenarios
relative to a 'control period' (2010-2085), without any climate change, were also used as a
referential. The influence of the number of equiprobable climatic scenarios used as input of the
hydrological model is examined later in this chapter (Section 7.4.1)
In Section 7.3.2, projected groundwater levels and surface water flow rates from 2010 to 2085 are
examined, and the uncertainty linked to the natural variability of the climate is evaluated through
the calculation of confidence intervals. In Section 7.3.3, it is taken advantage of the fully transient
climate change scenarios to calculate the time of occurrence of a specific event and the
uncertainty surrounding it.
7.3.2 Evolution and uncertainty of projected groundwater levels and surface
water flow rates
Results concerning the evolution of projected groundwater levels and surface water flow rates at
the outlet of the catchment are presented from Figure 7.9 to Figure 7.13. Figure 7.9 and Figure
7.10 present the evolution of groundwater levels between 2010 and 2085 for the climatic models
ARPEGE_H and RCAO_E respectively. Figure 7.11 shows the mean groundwater levels
between 2010 and 2085 for the 6 climatic models and for the 'control period'. Figure 7.12 and
Figure 7.13 present a similar analysis for the monthly surface water flow rates at the outlet of the
catchment. At Figure 7.13, the evolution of flow rates are also shown separately for February and
7. Application of stochastic climate change scenarios on the Geer basin model
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August. For each climatic model, mean groundwater levels and mean surface water flow rates are
calculated for each day between 2010 and 2085, using the 30 scenarios results. These means
express the average behaviour of groundwater levels and flow rates given 30 outcomes. For all
climatic models and observation points, mean groundwater levels and flow rates present a
decreasing trend between 2010 and 2085. By the year 2085, mean groundwater levels are
expected to decrease by 7-20 m, and water flow rates at 'Kanne' are expected to decrease between
44% and 70%, in comparison to the mean groundwater levels of the 'control simulations'. This
decrease is slightly higher than what was expected using the same hydrological model with the
'quantile mapping bias corrected' climatic scenarios, which projects a decrease of 4-19 m and 37-
67%, respectively (see Section 6). The different curves of mean groundwater levels and surface
water flow rates also show clear seasonal variations, which are the combination of higher or
lower seasonal fluctuations visible on each individual scenario. The quick evolution of
groundwater levels and surface water flow rates during the first years of the simulations show
that the initial conditions are sometimes inadequate. This is of little importance since induced
differences are quickly reduced, within two or three years. Additionally, the change in
groundwater level and water flow rate is not calculated in comparison to this initial state but in
comparison to 'control simulations' without any climate change.
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Figure 7.9. Evolution of hydraulic heads at the 8 observation wells for 30 equiprobable climatic scenarios of
ARPEGE_H (2010 – 2085)
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Figure 7.10. Evolution of hydraulic heads at the 8 observation wells for 30 equiprobable climatic scenarios
of RCAO_E (2010 - 2085)
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Figure 7.11. Mean hydraulic heads at the 8 observation wells for each of the 6 climatic models (30 scenarios)
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Figure 7.12. Evolution of water flow rate at the outlet of the basin for 30 equiprobable climatic scenarios of
ARPEGE_H and RCAO_E (2010 - 2085)
Figure 7.13. Mean water flow rate at the outlet of the basin for each of the 6 climatic models (30 scenarios)
The added value of using a large number of stochastic climatic scenarios is that it enables to
evaluate the uncertainty linked to the natural variability of climate. Figure 7.14 present the mean
groundwater level at 'OTH002' and the mean water flow rate at the outlet of the catchment
('Kanne'), as well as the enveloping intervals containing 95% of the climate change scenarios for
7. Application of stochastic climate change scenarios on the Geer basin model
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the control simulations and the two contrasted climatic models ARPEGE_H and RCAO_E. For
each climatic model and for each particular time between 2010 and 2085, it means that the 'true'
future scenario has a probability of 0.95 to be included within the respective enveloping interval,
when considering only the uncertainty linked to the natural variability of climate. The 95%
intervals are calculated considering that the distributions of groundwater levels and surface water
flow rates at each specific time are normal and lognormal, respectively. The results presented at
Figure 7.14 show that the enveloping intervals related to the different climatic models and the
'control simulations' are overlapping. This is observed just after 2010, but also at the end of the
century when climate changes are higher. The uncertainty linked to the natural variability of the
climate is then high, around 10 metres concerning groundwater levels at 'OTH002'. Nevertheless,
by the year 2085, the 95% intervals of ARPEGE_H and RCAO_E, which are expected to give
the lowest and highest decreases (see Figure 7.11), are entirely situated below the mean curve
related to the 30 'control' simulations. It indicates that, even if the uncertainty of projections
remains high, it is very likely that groundwater levels and surface water flow rates will decrease.
Finally, it should also be noted that the 95% interval tends to decrease with groundwater levels.
This is due to the increasing importance of the partially saturated zone which acts as a buffer and
attenuates all climatic fluctuations from the ground surface to the water table.
7. Application of stochastic climate change scenarios on the Geer basin model
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Figure 7.14. (A) Mean groundwater levels (30 scenarios) and 95% interval at observation point 'OTH002', (B) mean annual water flow rates (30 scenarios) and 95% interval at 'KANNE', for the control simulations
and the climatic models ARPEGE_H and RCAO_E.
7.3.3 Temporal uncertainty of a specific event
As already mentioned, another advantage of using the 'weather generator' downscaling technique
is that it allows simulating the change of mean climatic statistics in a fully transient way. It is then
possible to evaluate the impact of 'cumulated' climate change on groundwater reserves, rather
than using stationary climatic models. Using fully transient climatic models also enables to make
additional interesting analyses for water management. With usual downscaling techniques, it was
possible to answer the question about the increase or decrease of groundwater levels for three
stationary climates, representatives of three specific time slices (2011-2040, 2041-2070, 2071-
2100). With the downscaling technique used in this chapter, it is also possible to make it in
reverse and answer the question about when is it expected to reach a specified decrease in
7. Application of stochastic climate change scenarios on the Geer basin model
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groundwater levels, and to evaluate the associated uncertainty. As an illustration, a specific
application is performed here for the Geer basin where the following question is answered:
"When is it expected to have a continuous 10 m decrease of the groundwater level at OTH002?"
For each climate change scenario, the year of occurrence of a first 10 m decrease, relatively to the
mean groundwater level of the control simulations, was pointed out. An additional criterion was
that the 10 m decrease must be observed during 10 consecutive years after its first occurrence. To
overcome the effect of seasonal variations which could bias the analysis, yearly groundwater
levels were used. At Figure 7.15, the different years of occurrence are regrouped into 8 time
intervals between 2010 and 2085, and the number of outcomes for each time interval is plotted
separately for each climatic model. The climatic models RCAO_E and HIRHAM_E project the
fastest decreases. Inversely, ARPEGE_H shows a wider distribution with the highest numbers of
realisations occurring latter in the century. Using these distributions, it is then possible to evaluate
the uncertainty of the time of occurence and to calculate some confidence intervals. At Figure
7.16, a probability density function (pdf) of mean and standard deviation equal to 2040 and 15,
respectively, is associated to the distribution of HIRHAM_H. According to this normal pdf, the
95% interval for year of occurrence would be included between 2010 and 2069. This interval is
wide and is also probably influenced by the large natural multi-annual variability of groundwater
levels in the Geer basin.
To conclude, this kind of analysis can be easily reproduced for each climatic model, for each
location in the basin and for any particular impact.
7. Application of stochastic climate change scenarios on the Geer basin model
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Figure 7.15. Number of outcomes (10 m decrease in OTH002 groundwater level) for each time interval and
each climatic model.
Figure 7.16. Probability density function and 95% interval for HIRHAM_H (OTH002)
7.4 Verification simulations of modelling hypotheses
7.4.1 Influence of the number of equiprobable climatic scenarios
In the previous analysis, only 30 stochastic scenarios for each climatic model (GCM – RCM)
have been used as input of the hydrological model, though 100 scenarios have actually been
generated for each of them. This choice was made because of very large computing times. A
unique simulation between 2010 and 2085 with daily input precipitation and potential
7. Application of stochastic climate change scenarios on the Geer basin model
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evapotranspiration takes more than 20 days on a 3.0 Ghz Pentium4 desktop machine equipped
with 4 Gb RAM. Considering the number of scenarios and climatic models, it results a huge
volume of calculation to be performed by computers, and the question arises about the adequate
number of climatic scenarios to be used for each climatic model. To answer this question, 100
scenarios of ARPEGE_H have been used as input of the hydrological model and the results are
here compared with the previous ones, performed using 30 scenarios only. These comparisons
are shown at Figure 7.17 and Figure 7.18. Figure 7.17A shows the mean groundwater level and
the 95% interval at the observation point 'OTH002' between 2010 and 2085, calculated using 30
and 100 climatic scenarios of ARPEGE_H. The difference between both cases is very small.
Although the multi-annual slope of the mean groundwater curve and of the 95% interval limits
are more regular when using 100 scenarios, results and underlying interpretations remains
basically identical. Conclusions are similar concerning the annual flow rates at the outlet of the
catchment (see Figure 7.17B). At Figure 7.18, a similar comparison is performed with the years of
occurrence of a first 10 m decrease in groundwater level at 'OTH002' during a minimum period
of 10 years. The statistical distributions are evaluated successively for 30 and 100 scenarios of
'ARPEGE_H'. The probability density functions are then associated to these distributions, using
the calculated means and standard deviations, and the intervals containing 95% of the outcomes
are finally calculated. Using 30 climatic scenarios, the 95% interval is included between 2015 and
2077 around a mean of 2046. Using 100 climatic scenarios, the 95% interval is included between
2015 and 2082 around a mean of 2048. Although there is a difference between both cases,
especially for the upper limit of the 95% interval, this difference remains low in comparison to
the width of the interval. Nevertheless, using more scenarios may help identifying more easily the
type of distribution that characterises the different outcomes of the test. At Figure 7.18, the
distribution obtained from the 100 scenarios fits better a normal law than the distribution
obtained using only 30 scenarios.
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Figure 7.17. Results comparison when using 30 or 100 equiprobable scenarios of the climatic model
ARPEGE_H. (A) Mean groundwater levels and 95% interval at observation point 'OTH002'. (B) Mean annual water flow rates and 95% interval at 'KANNE'.
Figure 7.18. Comparisons of probability density functions and 95% intervals for ARPEGE_H (OTH002)
using 30 and 100 equiprobable scenarios. The vertical dotted lines represent the limits of the 95% interval.
7. Application of stochastic climate change scenarios on the Geer basin model
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7.4.2 Influence of the time discretisation
Another possibility for reducing computing times is to input all stresses (precipitations, potential
evapotranspiration and water abstraction volumes) on a monthly basis, using monthly means,
instead of daily means. Using smoothed stress factors allows expecting to have longer adaptive
time steps in HydroGeoSphere and thus shorter total simulation times. However, it may also be
expected that smoothed variations can also induce discrepancies in the modelling results as
compared to daily stress factors. Indeed, if precipitation and potential evapotranspiration are
smoother with lower extremes, this may have a significant impact on run-off and groundwater
recharge and, consequently, on groundwater levels and 'base flow'. As an example, a heavy rain
occurring during a unique day will not have the same effect on groundwater recharge than the
same amount of precipitation distributed on a whole month. The objective here is thus to
evaluate (1) the benefit in simulation time and (2) the impact of using smoothed stress factors.
For 30 equiprobable scenarios of ARPEGE_H, climate change impacts on groundwater levels
and water flow rates at the outlet of the catchment were then evaluated using respectively daily
and monthly mean precipitation and potential evapotranspiration. When using monthly stress
factors, a simulation between 2010 and 2085 is reduced to approximately three days instead of
more than 20 days. The saved CPU time is then considerable. Means and 95% intervals between
2010 and 2085 are presented at Figure 7.19 for both cases. Figure 7.19A shows groundwater
levels at the observation point 'OTH002'. Figure 7.19B and C show monthly water flow rates at
'Kanne' for February and August respectively. Concerning groundwater levels, very little
differences between both cases are observed and mean groundwater levels from all 30 scenarios
are globally similar. The upper limit of the 95% interval is slightly higher when using monthly
inputs, indicating that the simulated groundwater recharge is slightly more important, especially in
periods of high groundwater levels. Differences appear when considering water flow rates at the
outlet of the catchment ('Kanne'). The upper limit of the 95% interval and, to a lesser extent, the
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mean water flow rates are generally lower when using monthly precipitation and potential
evapotranspiration inputs. The 95% interval is reduced, indicating a decrease in the flow rate
variability and a lower dependance of flow rates at the outlet of the catchment to surface run-off.
For February and August, the maximum decreases of the 95% interval are equal to -30.6% and -
27.3%, respectively. This observation is in accordance with the use of mean monthly stresses
which smooth all precipitations events and favour water infiltration rather than surface run-off.
The lower limits of the 95% intervals are however unchanged when using daily or monthly
inputs. This is due to the fact that the lowest monthly flow rates occur during very dry periods
with none or very few precipitation events. During these periods, flow rates in rivers are basically
equal to the groundwater discharge or 'base flow' and the influence of using daily or monthly
precipitations is therefore quite limited.
Considering all these observations and interpretations, the impact of using monthly mean stresses
remains quite limited with the Geer basin model. Although significant decreases in the upper
limit of the 95% intervals can be observed, mean groundwater levels and mean flow rates from
all scenarios are very similar. This small influence can be explained by geographical and
hydrogeological considerations. First, the thick layer of unsaturated loess located above the chalk
aquifer smoothes infiltration between the ground surface and the top of the water table (see
Section 4). The influence of daily precipitations is then already limited. Second, the Geer basin is
characterised by very flat areas, where run-off is limited. Water in the Geer River is then mostly
fed by groundwater discharge, less sensitive to daily precipitations.
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Figure 7.19. Results comparison when using daily or monthly input solicitations for 30 equiprobable
scenarios of the climatic model ARPEGE_H. (A) Mean groundwater levels and 95% interval at observation point 'OTH002'. (B) Mean monthly water flow rates and 95% interval at 'KANNE' (February). (C) Mean
monthly water flow rates and 95% interval at 'KANNE' (August).
7. Application of stochastic climate change scenarios on the Geer basin model
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7.5 Discussion
The objectives of the study presented in this section were to (1) simulate flow conditions using
climatic scenarios that simulate climate change in a full transient way between 2010 and 2085; and
(2) to evaluate the uncertainty of projected groundwater levels and surface flow rates, due to the
natural variability of the weather. To reach these objectives, a state-of-the-art 'weather generator'
downscaling technique have been used to generate a large number of equiprobable stochastic
scenarios simulating full transient climate change between 2010 and 2085, for each of 6 different
climatic models (GCM – RCM) and for an additional 'control' climatic model without any climate
change. These climate change stochastic scenarios have then been applied as input of the Geer
basin hydrological model. This methodology constitutes a real innovation since such stochastic
climate change scenarios have never been used in combination with hydrological models. Here,
the advantages of these climatic scenarios are additionally combined with those of a fully
integrated surface – subsurface hydrological model, and this innovative methodology is one of
the most advanced in the fields of groundwater modelling and climate change.
The application of 30 climate change scenarios, for each climatic model (GCM – RCM), as input
of the Geer basin model enabled to calculate 95% confidence intervals around projected
groundwater levels and surface flow rates, for each specific time between 2010 and 2085. Results
show that these confidence intervals are relatively wide, especially when adding the uncertainty
linked to the use of different regional and global climatic model (GCM – RCM), as shown in
Figure 7.14 for observation point 'OTH002'. Although this total range of uncertainty is quite
high, it is however entirely located below the mean groundwater level of the 'control simulation'
at the end of the century. This indicates that it is very likely that groundwater levels will decrease,
even if the decrease intensity remains uncertain.
7. Application of stochastic climate change scenarios on the Geer basin model
154
As already mentioned, the main drawback linked to this methodology is the very large computing
time required to perform the hydrological simulations between 2010 and 2085. In this study, all
simulations were performed using 'NIC3', a super computer for intensive calculation at
University of Liège. This computer is equipped with 1296 different cores and enables to run large
numbers of simulations at the same time. Nevertheless, these kinds of computer are not always
available and several options when running hydrological simulations can be used to reduce
computing times. In Section 7.4.1, the influence of the number of climatic scenarios used as input
of the hydrological model is examined. The study showed that using only 30 equiprobable
scenarios for each climatic model is sufficient to get a satisfactory estimation of the mean
expected groundwater levels or surface water flow rates and the range of uncertainty around
these mean values. Using only 30 scenarios by climatic model then allows limiting computing
times as the total number of simulations is also reduced. Another way for reducing computing
times is to play on the time discretisation of the input stresses. With the Geer basin model, using
monthly mean precipitation and potential evapotranspiration rates instead of daily means enables
to increase the general size of the adaptive time steps and to reduce total computing time for
each simulation by a factor of 8 approximately. At section 7.4.2, a comparison of the impact
results, achieved with daily and monthly stresses, shows that the differences between both cases
are quite limited for the Geer basin hydrological model. The climate change impact calculated
with daily and monthly mean stresses are almost similar except a small increase of the uncertainty
intervals.
The results and conclusions achieved in this study are specific to the case of the Geer basin, and
have to be verified for each particular hydrogeological context and model. As an example, the
same analysis performed with the second hydrological model (calibrated using monthly mean
stresses) for which multi-annual variations are lower, would probably lead to different intervals.
As a consequence, and for a comprehensive analysis, the uncertainty linked to the natural
7. Application of stochastic climate change scenarios on the Geer basin model
155
variability of the climate has to be compared with other kind of uncertainty, such as the
uncertainty linked to the use of the hydrological model. It is the objective of Section 8, where all
uncertainty intervals are regrouped and compared.
7. Application of stochastic climate change scenarios on the Geer basin model
156
7.6 References
Blenkinsop, S., Fowler, H.J., Harpham, C., Burton, A. and Goderniaux, P., 2010. Modelling transient climate change with a stochastic weather generator. Projected temperature changes for the Geer catchment, Belgium. Journal of hydrology, submitted.
Burton, A., Fowler, H.J., Blenkinsop, S. and Kilsby, C.G., 2010. Downscaling transient climate change using a Neyman-Scott Rectangular Pulses stochastic rainfall model. Journal of hydrology, in press.
Burton, A., Kilsby, C.G., Fowler, H.J., Cowpertwait, P.S.P. and O'Connell, P.E., 2008. RainSim: A spatial-temporal stochastic rainfall modelling system. Environmental Modelling & Software, 23(12): 1356-1369.
Cowpertwait, P.S.P., 1991. Further developments of the Neyman-Scott clustered point process for modeling rainfal. Water Resources Research, 27(7): 1431-1438.
Kilsby, C.G., Jones, P.D., Burton, A., Ford, A.C., Fowler, H.J., Harpham, C., James, P., Smith, A. and Wilby, R.L., 2007. A daily weather generator for use in climate change studies. Environmental Modelling & Software, 22(12): 1705-1719.
Neyman, J. and Scott, E.L., 1958. Statistical approach to problems of cosmology. Journal of the Royal Statistical Society, Series B 20 (1): 1-43.
Watts, M., Goodess, C.M. and Jones, P.D., 2004. Validation of the CRU daily weather generator. BETWIXT Technical Briefing Note 4, Climatic Research Unit, University of East Anglia.
8. Uncertainty linked to the calibration of the model and summary of the results
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8. UNCERTAINTY LINKED TO THE CALIBRATION OF
THE MODEL AND SUMMARY OF THE RESULTS
8. Uncertainty linked to the calibration of the model and summary of the results
158
8. Uncertainty linked to the calibration of the model and summary of the results
159
8.1 Introduction and objectives
The objective of this chapter is to discuss and classify the diverse sources of uncertainty that may
affect the predictions of climate change impact on groundwater resources. In Section 7, the
'weather generator' downscaling technique enabled to generate a large number of equiprobable
climate change scenarios. The application of these scenarios as input of the Geer basin
hydrological model allowed assessing the uncertainty linked to the natural variability of the
climate. This kind of uncertainty relates to the physics of climatic phenomena. On the other
hand, additional uncertainty is linked to the modelling of these climatic and hydrologic
phenomena. The use of 6 different regional climate model experiments (GCM – RCM) allowed
evaluating the uncertainty linked to the existence of diverse general and regional atmospheric
models. Climate change impact on the Geer basin groundwater resources was also evaluated
using climatic scenarios generated with two different downscaling methods. An additional source
of uncertainty is linked to the use of hydrological models. As all kinds of numerical models,
hydrological models are actually simplified representations of the reality, developed for satisfying
specific objectives. They can be used for predictive purposes if they are able to satisfactorily
reproduce the reality, in accordance with the objectives of the study. This ability of models needs
to be carefully evaluated.
Section 8.2 presents the evaluation of the uncertainty linked to the calibration of the Geer basin
hydrological model. Section 8.3 summarises and compares all results about climate change impact
uncertainty in the Geer basin. Section 8.4 gives some conclusions.
8. Uncertainty linked to the calibration of the model and summary of the results
160
8.2 Estimation of the uncertainty linked to the calibration of the
hydrological model
The ability of hydrological models to reproduce the reality is determined by the model
calibration. The calibration of the Geer basin model has been evaluated in Section 5. However,
although this evaluation is needed, it is also not sufficient because it does not necessarily give
information about the accuracy and precision of predictions. A model which presents a good fit
to observed data may give poor predictions under stress conditions that are different from those
used in the calibration procedure (Henriksen et al., 2003; Hill and Tiedeman, 2007; Konikow and
Person, 1985; Refsgaard, 1997). This is particularly the case here where precipitation and
potential evapotranspiration vary under climate change conditions. Consequently, it is really
important to evaluate objectively the quality of the simulated predictions.
Several methods exist to evaluate the uncertainty linked to the calibration of models. The
'random sampling Monte Carlo' method consists in running many simulations with different
parameters values and examining what are the impacts on predictions (Bedford and Cook, 2001).
This method is quite straightforward but becomes difficult to implement when computing time
for each simulation is large. Additionally, it is sometimes hazardous to choose the ranges of
variations and statistical distributions that govern parameters values. In this study, the prediction
uncertainty linked to model calibration is quantified using the 'inferential methods' described in
details in Hill and Tiedeman (2007). Such methods are usually applied following a successful
termination of an automatic inverse calibration. They use the statistics describing the model fit to
observations and the results of the parameters sensitivity analysis (Sections 5.1.5.2 and 5.2) to
evaluate the uncertainty related to the estimated parameter values. This uncertainty calculated for
parameters is then related to the predictions uncertainty thanks to the calculated sensitivity of the
predicted values to the parameters. The general methodology and theory are described in Section
8. Uncertainty linked to the calibration of the model and summary of the results
161
8.2.1. The application of this methodology with the Geer basin hydrological model is presented is
Section 8.2.2. Results about climate change predictions uncertainty are presented in Section 8.2.2.
8.2.1 Methodology
Main concepts and equations of the method used in this chapter are briefly presented here after.
They come from Hill & Tiedeman (2007), where the method is described in details.
The conditions to apply the method are: (1) the conceptual model must be correct, (2) the
observation measurement errors must be unbiased, and (3) the calibrated model and simulated
residuals must be unbiased. While the first two conditions are verified before the model
construction or assumed, the third condition has to be verified through the evaluation of the
model fit at the end of the calibration procedure. The second step to estimate the parameters and
predictions uncertainty consist in evaluating the 'calculated error variance', using Equation 8.1, as
made in Section 5.1.5.2 for the Geer basin model. The weight for each observation is calculated
as the inverse of the true measurement error variance. As explained in Section 5.1.5.2, this
enables to account for the errors linked to the observations measurements and gives higher
weights to more certain observations. The theory presented here after is based on the assumption
that this weighting scheme is followed.
Calculated error variance : ( )[ ]
( )NParNObs
byyws
NObs
iiii
−
−=∑ 2
2'
(8.1)
iw : Weight for observation i
b : Vector of parameters
iy : Observed value i
iy' : Computed value i as a function of ( )b
8. Uncertainty linked to the calibration of the model and summary of the results
162
NObs : Number of observations
NPar : Number of parameters
The 'calculated error variance' expresses the variance of model errors (i.e. differences between
observed and computed values) for the calibration data set. This variance or uncertainty is related
to the parameters through the sensitivities of simulated values to parameters. In Equation 8.2,
0bijX are the components of the sensitivity matrix 0b
X calculated for the set of parameters 0b
from the optimised model. The matrix X has a number of rows and columns equal to the
number of observations and parameters, respectively.
j
ibij b
yX
∂∂
='
0 (8.2)
ijX : Sensitivity of the computed value i to the parameter j
iy' : Computed value i
jb : Parameter j
The parameter variance – covariance matrix ( )bV (NPAR × NPAR) is then calculated using
Equation 8.3. Linear confidence intervals on parameter values can be calculated with Equation
8.4, where the standard deviation of parameter j can be easily calculated using the corresponding
variance in the variance – covariance matrix ( )bV . A 95% linear confidence interval on a specific
parameter is the interval that has a 95% probability of containing the 'true' value of the
parameter.
8. Uncertainty linked to the calibration of the model and summary of the results
163
( ) ( ) 12 −⋅⋅×= XwXsbV T (8.3)
2s : Calculated error variance
X : Sensitivity matrix
w : Matrix containing all weights
( )jbj sntb ×−± 2/0.1, α (8.4)
( )2/0.1, α−nt : Student t-statistic
n : Degree of freedom (NObs - NPar)
α : Level of significance
jb : Parameter j
jbs : Standard deviation of the parameter j
These confidence intervals are useful when numerical models are used to get good estimation of
parameter values. However, it is usually not the case, and numerical models are more often used
for predictive purposes. In this context, it is more interesting to calculate confidence intervals on
predicted values. The uncertainty on parameter values can be related to the predictions by using
the sensitivities of the predicted values to the parameters. The prediction standard deviations can
be calculated using Equation 8.5. Linear 'individual' and 'simultaneous' predictions confidence
intervals are calculated using Equations 8.6 and 8.7 respectively. 'Individual' intervals have a given
probability of including the 'true' predicted value considering a unique prediction. 'Simultaneous'
intervals have the same given probability of including the 'true' predicted valued simultaneously
for all predictions. To illustrate the difference between both kinds of intervals, Hill and Tiedeman
(2007) take the example of 100 equivalent models with different sets of parameters. This example
is here adapted to the modelling of the Geer basin. A 95% 'individual' confidence interval for a
8. Uncertainty linked to the calibration of the model and summary of the results
164
predicted groundwater level at specific location and time will contain 95 of 100 simulated
groundwater levels independently of the other predictions (at other locations and times).
Concerning the 95% 'simultaneous' confidence intervals at each location and time, simulated
groundwater levels or flow rates from the same 95 of 100 models will be included in the intervals.
'Simultaneous' intervals are always equal or larger than the 'individual' intervals.
( )2
1
'''
⎥⎥⎦
⎤
⎢⎢⎣
⎡
∂∂
××∂∂
= ∑ ∑NPAR
i i
lNPAR
jij
j
lp b
pbV
bp
sl
(8.5)
lps ' : Standard deviation of the prediction l
lp' : Predicted value l
jb : Parameter j
( )bV : Parameters variance – covariance matrix
NPar : Number of parameters
( )lpsl sntp '2/0.1,' ×−± α (8.6)
( )lpBl skntp '2/0.1,' ×−± α (8.7)
( )2/0.1, α−nts : Student t statistic
( )kntB 2/0.1, α− : Bonferroni t statistic
n : Degree of freedom (# observations - # parameters)
α : Level of significance
lp' : Predicted value l
k : Number of simultaneous intervals
lps ' : Standard deviation of the prediction l
8. Uncertainty linked to the calibration of the model and summary of the results
165
Equations 8.6 to 8.7 allow calculating linear confidence interval for estimated parameters and
predictions. These linear intervals involves that the model is linear in the vicinity of parameter
values and, more particularly, that parameter sensitivities are constant within calculated intervals.
Linear intervals can be sufficient for moderately non-linear models. However, they become less
accurate as the degree of non linearity increases. Methods exist to calculate non-linear confidence
intervals and are described by Vecchia and Cooley (1987) and Hill & Tiedeman (2007). However,
they are very computationally intensive and they are impossible to apply with models that require
huge computing times. The appropriateness of calculating linear confidence intervals with the
Geer basin model is discussed later in Section 8.2.3.
8.2.2 Application of the methodology on the Geer basin hydrological model
The concepts and equations presented here above have been applied in the context of the climate
change impact study on the Geer basin groundwater resources. The objective is then to evaluate
the uncertainty of simulated groundwater levels and flow rates due to the use of the hydrological
model, under climate change conditions.
The methodology has been applied to the case of the Geer basin model calibrated with daily
stresses (calibration 1, see Section 5). The predictions correspond to monthly groundwater levels
and surface water flow rates at the same observation points as for the calibration procedure (8
observation wells and the 'Kanne' gauging station, see Figure 4.1), but under climate change
conditions. In this study, the predictions uncertainty has been evaluated for climate change
corresponding to the climatic model 'HIRHAM_H - 2071-2100' (Figure 6.1), which presents
medium climate change compared to the other RCMs. The predictions uncertainty is calculated
for absolute groundwater levels and flow rates and for the associated decreases in comparison
with the equivalent groundwater levels and flow rates without any climate change. When
calculating predictions sensitivities, this implies running twice more simulations for each
8. Uncertainty linked to the calibration of the model and summary of the results
166
parameter, as hydraulic conditions without climate change are needed to calculate the equivalent
decreases. To limit computing times, the 'predictive' period was limited to 6 years. It corresponds
to the solicitations of the period 1984 – 1990, scaled by the change factors of 'HIRHAM_H -
2071-2100' for the simulations with climate change. Predictions are evaluated after two years of
simulation to let the hydrological model accommodate the initial conditions.
Practically, it implies evaluating the calibrated model, calculating the observations sensitivities (i.e.
computed values corresponding to the observations of the calibration step with identical
solicitations) and calculating the predictions sensitivities. These analyses have been performed
using the computer code 'UCODE_2005' (Hill et al., 2003; Poeter et al., 2005). The evaluation of
the calibrated model and the observations sensitivities have been calculated for the period 1967 –
2003 and are presented in Section 5.2. As explained in Section 5.1.5.2, the weights of
groundwater level and surface water flow rates observations have been assigned so that the 95%
confidence interval including the true groundwater level is within 1 metre around the measured
groundwater level, and the coefficient of variation of the flow rate measurement errors is equal to
10%. Given these assumptions, the weights for observed groundwater levels are equal to 3.84m-2,
and the weights for surface water flow rates observations vary between 3.7 and 141.7 m-6s2. Using
these weights and the simulated variables, the 'calculated standard error' s, used in Equation 8.3,
is equal to 10.2. The observations sensitivities allow calculating the parameters variance –
covariance matrix7 (Equation 8.3), which is used in Equation 8.5 to calculate the prediction
uncertainty.
7 The parameters linked to the calculation of the actual evapotranspiration have not been adjusted during the calibration stage and are specified on the basis of prior information from the scientific literature. This prior information helps reducing the uncertainty on the parameters values and has been incorporated in the uncertainty evaluation by adding lines and columns in the matrices of Equation 8.3. More details about how to use prior information can be found in Hill and Tiedeman (2007).
8. Uncertainty linked to the calibration of the model and summary of the results
167
Predicted values and 95 % confidence intervals are presented in Figure 8.1 and Figure 8.2 for
groundwater levels at the 8 observation points and surface water flow rates at the outlet of the
catchment ('Kanne'), respectively. The mean range of the 'simultaneous' 95 % intervals around
absolute groundwater levels varies between 6.9 m at the observation point A7-PL37 and 28.9 m
at MOM001. The mean range of the 'individual' 95 % intervals around absolute groundwater
levels varies between 2.4 m and 9.8 m for the same observation points. Concerning surface water
flow rates, the mean 'simultaneous' and 'individual' 95% intervals are equal to 3.9 m³/s and 1.4
m³/s, respectively. The intervals are however larger for winter than for summer, with the
uncertainty also spreading in the area corresponding to flow rates increase. Generally, the
confidence intervals around predicted absolute values (Figure 8.1A) are generally similar to
equivalent intervals around predicted changes (Figure 8.1B). Though some variations of the range
of these intervals are observed during the 6-years time period, no clear trend can be identified, for
most of the observation points. At 'MOM001', however, the range of the confidence interval
clearly increases with time.
8.2.3 Discussions about the confidence intervals
The confidence intervals presented at Figure 8.1 and Figure 8.2 have 95 % chance of including
the 'true' predicted value considering the model calibration and the stresses specified for the
period of interest. These are linear confidence intervals, evaluated given the calibrated parameters
values and considering that all sensitivities are constant. As already explained, these sensitivities
can vary significantly with non-linear models, and this is obviously the case for the surface –
subsurface model used in this study. If non-linearity is severe, the linear confidence intervals can
become inaccurate. This is well illustrated at Figure 8.2A, where the linear 95% confidence
intervals of predicted flow rates spill out onto the area of negative flow rates. This situation is
obviously not realist and is due to the non-linear nature of the hydrological model, especially
when conditions become very dry. In this case, the lower limit of the flow rate linear confidence
8. Uncertainty linked to the calibration of the model and summary of the results
168
intervals is inaccurate and the lower range of the interval is overestimated. Vecchia & Cooley
(1987) developed an alternative method for calculating non-linear confidence intervals. However,
the method requires scanning ranges of variation of parameters values and performing several
sensitivity analyses to find to minimum and maximum predicted values. According to Hill and
Tiedeman (Hill and Tiedeman, 2007), calculating prediction non-linear intervals is often longer
and more difficult than performing a complete non-linear automatic regression of the parameters.
Considering the computing times for a single transient simulation with the Geer basin
hydrological model, this task was not feasible within reasonable times.
Additional source of potential inaccuracy of the confidence intervals relates to the fact that the
Van Genuchten parameters are not included in the analysis, due to technical incompatibility of
the input tables with 'UCODE_2005' processes (see Section 5.2). Though the Van Genuchten
parameters are not adjusted during the calibration stage and specified on the basis of laboratory
experiments (Brouyère, 2006), a limited uncertainty remains for these parameters. Neglecting it in
the evaluation of the uncertainty of the predictions could induce an underestimation of the
confidence intervals. Nevertheless, though inaccurate in some cases, the linear confidence
interval is a good indicator of the predictions uncertainty. They are particularly useful when
compared with uncertainty of other types, what is made in Section 8.3.
The different linear confidence intervals have been calculated with the first hydrological model
(Calibration 1). Results are specific for this model and could hardly be transposed to the case of
the second hydrological model (calibration 2) described in Section 5.4, or any other model.
However, performing the same uncertainty analysis with this second model is not possible as the
calibration results do not satisfy the conditions required for such an analysis. Actually, as shown
in Figure 5.9 to Figure 5.11, the second model presents a bias, with an overestimation of almost
all groundwater levels and surface water flow rates.
8. Uncertainty linked to the calibration of the model and summary of the results
169
Figure 8.1. Predictions and 95 % confidence interval around predicted values for 8 years of a HIRHAM_H
downscaled climate change scenario. (A) Absolute groundwater levels. (B) Groundwater levels change between a scenario without any climate change and the HIRHAM_H climate change scenario.
8. Uncertainty linked to the calibration of the model and summary of the results
170
Figure 8.2. Predictions and 95 % confidence interval around predicted values for 8 years of a HIRHAM_H downscaled climate change scenario. (A) Absolute surface water monthly flow rates. (B) Change in surface
water monthly flow rates between a scenario without any climate change and the HIRHAM_H climate change scenario.
8.3 Summary of the results about climate change impact uncertainty
In this study, several tools have been used to assess the uncertainty surrounding the climate
change impact estimations for the groundwater reserves of the Geer basin. The results achieved
are summarised and compared in Table 8.1, Figure 8.3 and Figure 8.4, for the period 2071-2100.
Uncertainty linked to Method Type of interval
calculated
Range of the interval for groundwater levels
(Min – Max)
Range of the interval for annual flow rates
('Kanne') (Min – Max)
the natural variability of the weather
use of 180 equiprobable climatic scenarios 95% confidence interval 2.3 – 18.6 m 1.01 – 2.55 m³/s
the climatic models use of 6 RCMs
experiments total range of variation 3.2 – 11.3 m 0.99 m³/s
the calibration of the hydrological model
inferential statistical methods
('UCODE_2005')
95% linear confidence interval 6.9 – 28.7 m 3.92 m³/s
the downscaling method
use of 2 different downscaling method total range of variation 0.7 – 4.8 m 0.05 – 0.35 m³/s
Table 8.1. Summary of the results about climate change impact uncertainty for the period 2071-2100 (calculated with the first hydrological model, calibrated with daily stresses).
8.3.1 Uncertainty linked to the natural variability of the climate
The uncertainty linked to the natural variability of the climate has been evaluated using a large
number of equiprobable climate change scenarios generated using the 'CRU weather generator'
downscaling technique. The whole set of projected groundwater levels and flow rates has then
8. Uncertainty linked to the calibration of the model and summary of the results
171
been used to calculate 95% confidence intervals (see Section 7). The range of groundwater levels
confidence intervals varies between 2.3 m and 18.6 m depending on the observation point and
the climatic model. Annual flow rates confidence intervals vary between 1.01 and 2.55 m³/s,
depending on the climatic model (Table 8.1), with larger intervals during winters than during
summers. Generally, the range of the confidence intervals tends to decrease as the importance of
the partially saturated zone, which smoothes the climatic variations, becomes higher.
8.3.2 Uncertainty linked to the climatic models
Uncertainty has been evaluated from various possible sources, by using several different input
possibilities or by using more complex methods allowing the calculation of confidence intervals.
The first source of uncertainty is linked to the general and regional climatic models (GCMs and
RCMs) used before applying statistical downscaling. This source is the only one considered in
most existing studies about groundwater and climate change. Here, the possible range of
variation for projected groundwater levels has been evaluated using 6 different RCMs with
boundary conditions from 2 different GCMs (see Table 6.1). This number is limited but has been
maximised from the PRUDENCE ensemble by the choice of the climatic models, as explained in
Section 6. The ranges of variation of groundwater levels and flow rates due to this source of
uncertainty are mainly dependent on the location in the Geer basin and the hydrological model
used. The highest and lowest decreases are usually projected by 'HAD_P_H' and 'ARPEGE_H',
respectively.
8.3.3 Uncertainty linked to the downscaling technique
In this study, two statistical downscaling techniques have been used to downscale RCMs outputs:
the 'Quantile Mapping Bias Correction' technique and the 'CRU weather generator'. The
projected mean groundwater levels achieved from both kinds of downscaled climatic data are
very similar, though decreases are slightly more important with the 'weather generator'
8. Uncertainty linked to the calibration of the model and summary of the results
172
downscaled data. This difference remains anyway very small compared to the uncertainty from
other possible sources. However, it should be noted that the two downscaling techniques used
here are part of the most sophisticated, both of them involving corrections not only to the mean
of climatic variables but also across their statistical distribution. Therefore, it is finally consistent
that the difference is small. Discrepancies would probably be higher if comparisons between
sophisticated downscaling methods and more simple ones were performed.
8.3.4 Uncertainty linked to the calibration of the hydrological model
Finally, the uncertainty linked to the calibration of the hydrological model was estimated by
coupling 'UCODE_2005' with 'HydroGeoSphere' (Section 8.2). The mean range of the 95%
confidence intervals around predicted groundwater levels varies between 6.9 m and 28.7 m. The
mean confidence interval around predicted flow rates is equal to 4.1 m³/s (Table 8.1), with larger
intervals during winters than during summers. This kind of uncertainty was also previously
'tested' by using two hydrological models with different calibrations. As already mentioned, the
second model (calibration 2) gives significantly less important decreases for the period 2071-
2100. As shown in Figure 8.3, these differences between both models are sometimes more
important than the range of the equivalent confidence interval calculated with 'UCODE_2005'.
Several reasons can explain these greater differences. (1) The confidence intervals are linear and
may be inaccurate where the model presents too important non-linearity (see Section 8.2.3). (2)
The calibration of the second hydrological model presents a significant bias (see Section 5.4) and
does not satisfy the conditions necessary to apply the statistical methods used in 'UCODE_2005'.
Therefore, it is also hazardous to compare the results of this model with confidence intervals
produced by 'UCODE_2005'. (3) The range of the 95% confidence interval may be
underestimated because the Van Genuchten parameters are not included in the analysis (see
Section 8.2.3). (4) Finally, the 95% confidence intervals cover only 95% of the whole set of
possibilities, by definition.
8. Uncertainty linked to the calibration of the model and summary of the results
173
Figure 8.3. Summary of all results and uncertainties for the 8 groundwater observation points. The
horizontal red line represents the 'control' mean groundwater level without any climate change.
8. Uncertainty linked to the calibration of the model and summary of the results
174
Figure 8.4. Summary of all results and uncertainties for the water flow rate at the outlet of the catchment
('Kanne'). The horizontal line represents the 'control' mean flow rate without any climate change.
8.4 Conclusions about uncertainty
The research works performed in the framework of this PhD thesis enabled to evaluate the
uncertainty from various sources. Following the summary of the results presented here above, it
is possible to rank these sources of uncertainty from the most to the less significant. The
uncertainties linked to the calibration of the hydrological model and the natural variability of the
climate appear to be the most important in this case. The uncertainty linked to the use of
different general and regional climatic models (GCMs and RCMs) comes in third position,
followed by the uncertainty linked to the use of downscaling methods. This evaluation of
uncertainties and their ranking is specific to this study and could hardly be transposed to other
models or case studies, without a detailed analysis. Nevertheless, it could constitute a guide in the
arduous and difficult task of uncertainty evaluation. Particularly, it shows the importance and the
usefulness of evaluating the uncertainty linked to the calibration of the model.
8. Uncertainty linked to the calibration of the model and summary of the results
175
Among all uncertainties summarised here, two different kinds have to be differentiated. First, the
uncertainty linked to the natural variability of the climate is inherent to the climatic phenomenon,
and can not be eliminated whatever happens. Calculated intervals do not traduce a model 'error'
but express how groundwater levels or surface water flow rates will inevitably vary with time
around an average position, due to the occurrence of dry and wet periods. At the other hand, the
other uncertainties are linked to 'errors' or 'approximations' made in climate or hydrological
modelling. The direction of the simulated 'error' does not necessarily vary with time. These
uncertainties can be reduced by improving the models or the knowledge necessary to implement
them. As an example, a model that fits better the observations will also gives more confident
predictions.
Finally, additional sources of uncertainty have not been considered in this study. All climatic
scenarios used here correspond to the A2 greenhouse gases emissions scenario (medium-high)
(see Section 2.3.3). Considering lower emissions, such as the B2 scenarios (medium-low), would
lead to less important changes. Déqué et al. (2007) however showed that, when using climate
models, the uncertainty from emissions scenarios was lower than the uncertainty from GCMs
and RCMs over Belgian latitudes. Another uncertainty not considered in this study is linked to
the conceptual model used when implementing the hydrological model. This uncertainty relates
to potential changes that would be induced by other boundary conditions, different numbers of
finite elements in the grid or alternative zonations of the hydraulic properties, for example. The
evaluation of such uncertainty has been studied by Rojas (2009) and Rojas et al. (2009) for a
regional aquifer in Chile, but not in the context of climate change impact.
Considering all these results about impacts and uncertainties, it is very likely that groundwater
levels in the Geer basin will decrease by the end of the century, due to climate change. Actually,
calculated impacts from both hydrological models project significant decreases over the whole
basin for this period. Additionally, most part of the confidence intervals or ranges of variations
8. Uncertainty linked to the calibration of the model and summary of the results
176
(Figure 8.3) are comprised below the 'control' groundwater level corresponding to the 1980s
climate without any change. Considering all uncertainties, it is however more difficult to evaluate
what will be the intensity of the decrease. Some confidence intervals are actually large compared
to the projected decreases. Furthermore, the uncertainties related to modelling 'errors' or
approximations (calibration of the hydrological model, climatic downscaling techniques,
modelling of general or regional models, etc.) may superimposed, inducing larger global
uncertainty around final predicted values. Concerning surface water flow rates at the outlet of the
catchment, conclusions are similar for annual flow rates. Uncertainty is however larger for winter
flow rates than for summer flow rates, with the uncertainty also spreading in the area
corresponding to flow rates increase.
8. Uncertainty linked to the calibration of the model and summary of the results
177
8.5 References
Bedford, T. and Cook, R.M., 2001. Probabilistic Risk Analysis, Foundations and Methods. Cambridge University Press., Cambridge, UK.
Brouyère, S., 2006. Modelling the migration of contaminants through variably saturated dual-porosity, dual-permeability chalk. Journal of Contaminant Hydrology, 82: 195-219.
Déqué, M. et al., 2007. An intercomparison of regional climate simulations for Europe: assessing uncertainties in model projections. Climatic Change, 81(0): 53-70.
Henriksen, H.J., Troldborg, L., Nyegaard, P., Sonnenborg, T.O., Refsgaard, J.C. and Madsen, B., 2003. Methodology for construction, calibration and validation of a national hydrologic model for Denmark. Journal of Hydrology, 280: 52-71.
Hill, M.C., Poeter, E., Zheng, C. and Doherty, J., 2003. MODFLOW 2001 and other modeling odysseys. Ground Water, 41(2): 113.
Hill, M.C. and Tiedeman, C.R., 2007. Effective groundwater model calibration. With Analysis of data, sensitivities, predictions and uncertainty. John Wiley & Sons, New Jersey, 455 pp.
Konikow, L.F. and Person, M., 1985. Assessment of Long-Term Salinity Changes in an Irrigated Stream-Aquifer System. Water Resour. Res., 21.
Poeter, E.P., Hill, M.C., Banta, E.R., Mehl, S. and Christensen, S., 2005. UCODE_2005 and Six Other Computer Codes for Universal Sensitivity Analysis, Calibration, and Uncertainty Evaluation: U.S. Geological Survey Techniques and Methods 6-A11, 283 pp.
Refsgaard, J.C., 1997. Parameterisation, calibration and validation of distributed hydrological models. Journal of Hydrology, 198(1-4): 69-97.
Rojas, R., 2009. Uncertainty analysis in groundwater modelling: An integrated approach to account for conceptual model uncertainty. PhD Thesis, Katholiek Universiteit Leuven. Faculty of Science, Leuven, 150 pp.
Rojas, R., Batelaan, O., Feyen, L. and Dassargues, A., 2009. Assessment of conceptual model uncertainty for the regional aquifer pampa del Tamarugal. Hydrology and Earth System Sciences Discussions, 6(5): 5881-5935.
Vecchia, A.V. and Cooley, R.L., 1987. Simultaneous confidence and prediction intervals for nonlinear regression models with application to a groundwater flow model. Water Resources Research, 23(7): 1237-1250.
8. Uncertainty linked to the calibration of the model and summary of the results
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9. Conclusions and perspectives
179
9. CONCLUSIONS AND PERSPECTIVES
9. Conclusions and perspectives
180
9. Conclusions and perspectives
181
9.1 Conclusions
The objectives of this research are the following:
(4) development of a methodology for a reliable estimation of the climate change impacts on
groundwater reserves;
(5) estimation of the uncertainty characterising these projected impacts, considering various
possible uncertainty sources;
(6) pilot application of the two first objectives on the case of the Geer basin catchment
(Belgium).
These objectives have been set in response to the lack of research carried out in the fields of
climate change and groundwater. They also respond to some gaps or oversimplifications made in
previous studies. This study then presents a robust methodology and guidelines that can be used
to assess impacts of climate change on groundwater reserves and the uncertainties surrounding
these. The methodology provides new outcomes at three levels: hydrological modelling, climate
change scenarios, and methods for uncertainty evaluation. This new methodology has been
applied to the case of the Geer basin groundwater reserves.
9.1.1 Hydrological modelling
To assess the climate change impact on groundwater reserves of the Geer basin, a 'physically-
based', 'spatially-distributed', integrated surface – subsurface hydrological model has been
developed with the finite element code 'HydroGeoSphere'. This model enables a more realistic
representation of the system for three reasons:
9. Conclusions and perspectives
182
- Interconnected flow processes, such as groundwater recharge, are better represented because
the flow equations are solved simultaneously in all domains (surface, partially saturated zone,
saturated zone).
- Integrated models allow using both surface and subsurface observed data in the calibration
procedure. Compared to stand-alone groundwater models, this reduces correlations between
parameters and enables to check more easily that some components of the water balance are
well represented.
- The model is 'physically-based', which is more indicated especially when extrapolations are
made.
This study also outlines the importance and usefulness of a reliable and objective evaluation of
the calibration. The calibration of the Geer basin model has been evaluated using weighted
residuals which enable to better identify possible biases in the model.
9.1.2 Climate change scenarios
The climate change scenarios used in this study have been statistically downscaled from RCMs
using two different downscaling techniques: the 'Quantile Mapping Bias Correction' technique
and the 'Weather Generator' ('RainSim' and 'CRU' WG). Both of them are sophisticated
techniques and are able to project changes not only to the mean values of climatic variables but
also to the shape of their statistical distribution. The 'Quantile Mapping Bias Correction'
technique is used to generate one climatic scenario for 30-years time periods representing a
stationary climate over the selected period. The 'weather generator' technique is even more
sophisticated. It enables to generate large numbers of equiprobable climatic scenarios,
representative of a transient climate change between 2010 and 2085. When applying these
scenarios as input of hydrological models, they offer the opportunity to evaluate impact from a
9. Conclusions and perspectives
183
probabilistic point of view. Because they simulate full transient climate change, they also enable
to analyse the timing of potential impact. Nevertheless, running many climate change scenarios as
input of hydrological models requires important computer resources. Both techniques then
present specific advantages. The choice of the technique to be used depends on the objectives of
the study and the computing resources available.
In this study, it was also examined the effect of using larger time steps, which could substantially
reduce the total time of calculation, particularly when applying a large number of different climate
change scenarios. With the Geer basin model, it was shown that using mean monthly input
stresses instead of daily inputs implies limited changes in the range of confidence intervals. It was
also shown that applying 100 or 30 equiprobable climate change scenarios as input of the
hydrological model leads to very similar results.
9.1.3 Uncertainty evaluation
The uncertainty affecting projected groundwater levels has been evaluated regarding various
uncertainty sources.
- The uncertainty linked to the climatic models has been evaluated by using a multi-model
ensemble RCMs and GCMs.
- The uncertainty linked to the natural variability of the climate has been estimated by applying
a large number of equiprobable climatic scenarios as input of the Geer basin hydrological
model. Climatic scenarios have been generated with 'RainSim' and the 'CRU Weather
Generator'.
- The uncertainty linked to the downscaling procedure has not been studied extensively. Only
two different techniques, among the most advanced, have been tested to generated climate
change scenarios and apply them as input of the Geer basin hydrological model
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184
- The uncertainty linked to the calibration of the hydrological model has been evaluated using
the capabilities of the computer code 'UCODE_2005'.
9.1.4 Impact for the Geer basin
The climatic models relative to the Geer basin area project a pattern of much hotter and drier
summers and warmer and wetter winters. According to these models, the annual temperature
mean change varies between +3.1°C and +5.6°C, and the annual precipitation mean change
varies between -1.9% and -15.3%, for the period 2070-2100. Considering these climatic models
and the results achieved in this study, it is very likely that groundwater levels will significantly
decrease by the end of the century. For the period 2070-2100, groundwater levels are expected to
decrease by 2-19m depending on the location in the Geer basin, the climatic and hydrological
models. For the same period, annual water flow rates at the outlet of the catchment are expected
to decrease by 9% - 65%, with a more pronounced change during summers than during winters.
This is of concern because it also means that the groundwater quantities available for abstraction
will also decrease, while the aquifer is already intensively exploited. Furthermore, the water
demand may increase in the future, due for example to an intensification of irrigation practices.
For the period 1967-2003, mean groundwater abstraction represents 6.4% of precipitation or
~16% of the 'effective water'. 'Effective water' is equal to precipitation minus actual
evapotranspiration, and should then be partitioned between groundwater recharge and surface
runoff. Considering the results of Table 6.2 and Table 6.3, and the assumption that groundwater
abstraction will remain constant over the 21st century, it is expected that the proportion of
groundwater abstraction relatively to the 'effective water' term would be included between 16%
and 44% by the end of the century, depending on the climatic and hydrological models used.
However, this study also showed that the uncertainty surrounding projected groundwater levels
in the Geer basin are relatively large. Consequently, it remains difficult to state on the intensity of
9. Conclusions and perspectives
185
the decrease with high confidence. Main uncertainty is linked to the natural variability of the
climate and the calibration of the hydrological model. While the first one expresses how
groundwater levels will vary around a mean position, the second one relates to modelling
'approximations' and could be reduced by improving the model calibration, if needed.
9.1.5 General conclusion
The methodology developed in this study combines the advantages of a fully-integrated surface –
subsurface model, sophisticated climate change scenarios and methods to evaluate uncertainties
from various sources. The tools applied in this study have never been used previously in the
context of climate change impact on groundwater reserves. Their use and combination
constitutes an innovation and advances the study of climate change impacts on groundwater
reserves. Particularly, the fact that projections are calculated along with uncertainties gives
credibility to the study and constitutes a very important tool for helping water managers to take
decisions. Results achieved in this thesis are specific to the case study of the Geer basin but the
methodology applied and the main conclusions about it can be reproduced in other catchments
and contexts.
9.2 Perspectives
The integrated surface – subsurface model of the Geer basin offer numerous additional
applications for river basin management. The present study focuses on the direct impacts of
climate change on groundwater reserves but other factors may also affect indirectly but
importantly, the groundwater reserves in the context of climate change. Examples of such factors
are the evolution of land use or changes to agricultural practices. Through the use of appropriate
scenarios, it should be possible to test the influence of such indirect factors on the Geer basin
groundwater reserves. Similarly, the model could also be used to examine what would be the
effect and usefulness of mitigation measures such as artificial recharge for example. Additionally,
9. Conclusions and perspectives
186
problems of contaminant accumulation (e.g. salts, pesticides, fertilisers) are commonly observed
in basins characterised by intensive agriculture activities. These issues offer new opportunities to
further use and develop the model to address contaminant transport problems.
One difficulty of using catchment scale integrated models lies in the fact that computing times
can become very large. This issue prevents of makes difficult some applications. As examples, an
inverse automatic calibration or the calculation of non-linear confidence intervals with
'UCODE_2005' was not possible in this study, due to unworkable computing times.
Nevertheless, a lot of research is currently performed in the field of integrated modelling, and
future new developments may help reducing these times. Particularly, most of the computing
codes which perform integrated surface – subsurface flow simulations will shortly be able to run
simulations on several processors in parallel. Other developments also include the simplification
of flow calculation in the partially saturated zone. Calculating one-dimensional vertical flow
instead of three-dimensional flow in this zone might significantly reduce computing times
without affecting too much the performance of the model. Such new developments that will
facilitate the calibration and other applications should also improve the attractiveness of long-
term catchment-scale integrated modelling.
Appendix
187
APPENDIX
Appendix
188
Appendix
189
Parameterisation of the second Geer basin hydrological model, calibrated
with monthly stresses
Van Genuchten parameters Residual water saturation Total porosity Specific storage
α [L-1] β [-] Swr [-] n [-] Ss [L-1]
Chalk formations 0.099 1.10 0.023 0.44 1×10-4
Loess formations 7.57 1.16 0.024 0.41 1×10-4
Table A2. Van Genuchten parameters, total porosity and specific storage
Name K [LT-1]
Chalk 1 4×10-5 Chalk 2 1×10-3 Chalk 3 3×10-5 Chalk 4 2×10-6 Chalk 5 2×10-5 Lo
wer
cha
lk
Chalk – Dry valleys 2×10-4
Chalk 1 1×10-4 Chalk 2 1×10-3 Chalk 3 1×10-5 Chalk 4 1×10-4 Chalk 5 5×10-5
Inte
rmed
iate
cha
lk
Chalk – Dry valleys 2×10-4
Chalk 1 1×10-4 Chalk 2 1×10-3 Chalk 3 1×10-4 Chalk 4 1×10-4 Chalk 5 1×10-4 U
pper
cha
lk
Chalk – Dry valleys 2×10-4
Quaternary loess 1×10-8
Tertiary deposits 0.3×10-7 - 1×10-7
Table A3. Full saturated hydraulic conductivities values of the calibrated zones (results of calibration)
X-Y friction [L-1/3T] Coupling length [L-1/3T]
Rural 3 0.01
Urban 0.3 0.01
Forested 6 0.01
Table A4. Values for the Manning roughness coefficients and coupling length
Appendix
190
Rural crop (temperate)
Rural grassland (temperate)
Rural broadleaf deciduous forested
(temperate) Urban
Root depth Lr [L] 2.1 2.6 5.2 0.0
Evaporation depth Le [L] 2.0
Max. LAI [-] 4.22 2.50 5.12 0.40
Cint [L] 1×10-5
C1 [-] 0.3
C2 [-] 0.2
C3 [-] 10
Table A5. Root depths, evaporation depths and Leaf Area Index
Rain Actual evapotransp. North boundary Outlet (‘Kanne’) Water abstraction Water balance
error
mm/year 798.6 -502.3 -37.5 -209.2 -51.1 1.5
% of rainfall 100 -62.9 -4.7 -26.2 -6.4 0.2
Table A6. Simulated mean water balance terms for the period 1967-2003
Goderniaux P., 2010. Impact of Climate Change on Groundwater Reserves. PhD Thesis. University of Liège, Faculty of Applied Sciences. Liège, Belgium. pp. 190.