Post on 13-Jan-2016
description
Land-use effects on spatial and temporal patterns of carbon storage and flux in PNW forests
David WallinDepartment of Environmental Sciences
Huxley College of the Environment
Western Washington University
Bellingham, WA
Collaborators
• Peter Homann: Dept. of Environmental Sciences, Huxley College, WWU
• Mark Harmon: Dept. of Forest Science, Oregon State University
• Warren Cohen: USDA Forest Service, PNW Research Station
• Olga Krankina: Dept. of Forest Science, Oregon State University
Why is the global carbon cycle important?
• All life on the planet is based upon the cycling of carbon
Carbon Cycling
Photosynthesis
6CO2 + 12H20 Life 6O2 + C6H12O6 + 6H20
Respiration
Photosynthesis and respiration are among the most important mechanisms controlling the global carbon cycle
Plants use CO2 from the atmosphere as a source of both C and O for the production of glucose (C6H12O6), with H20 providing the necessary H
Carbon Cycling
Glucose (C6H12O6) is the central carbohydrate compound of protoplasm, and carbohydrates constitute a large percentage of the total dry biomass of plants. Glucose is composed of:
6 atoms of C; atomic wt = 12 72
6 atoms of O; atomic wt = 16 96
12 atoms of H; atomic wt = 1 12 ----
180
So, (72 + 96)/180 = 0.93
93% of the mass of the glucose molecule is derived directly from air!
Carbon Cycling
Plants, and animals, are composed of more than just C, O, and H; other important elements include N, P and K.
Nevertheless, about half of the dry biomass of plants is composed of C and this C is derived entirely from the atmosphere.
Why is the global carbon cycle important?
• All life on the planet is based upon the cycling of carbon
• Atmospheric concentrations of CO2 have increased substantially over the past century or so, largely as a result of the combustion of fossil fuels
Long-term variation in atmospheric CO2 concentrations: The Vostok ice core
Recent trends in atmospheric CO2 concentrations: The role of fossil fuel burning
Even more recent records reveal that atmospheric CO2 concentrations continue to increase
Why is the global carbon cycle important?
• All life on the planet is based upon the cycling of carbon
• Atmospheric concentrations of CO2 have increased substantially over the past century or so, largely as a result of the combustion of fossil fuels
• CO2 is a “greenhouse gas” and, as such, increasing atmospheric concentrations of CO2 have the potential to cause major changes in the earth’s climate
A “Greenhouse Gas”; What does this mean?
• I. The Electromagnetic Spectrum
A “Greenhouse Gas”; What does this mean?
• II. Sources of EM Energy– The amount of energy emitted by an object (area under the
curve) and the wavelength of peak emission area function of the temperature of the object
A “Greenhouse Gas”; What does this mean?
• III. Interaction of EM energy with solids, liquids and gasses
A “Greenhouse Gas”; What does this mean?
• IV. Greenhouse gasses absorb EM energy very strongly at wavelengths (8-10 um) where the earth is emitting EM energy to space. This results in a warming of the atmosphere.
Major reservoirs in the global carbon cycle
Atmosphere 748 PgTerrestrial 2,000 PgOceans 38,000 PgGeologic 4,000 Pg
The geologic stores of recoverable fossil fuels were arelatively inactive reservoir in the global carbon cycle prior to the industrial revolution.
Pg = 1015 grams
Sources and Sinks in the global carbon budget: 1980-1995
Fossil fuel combustion 5.7 Pg C/yrLand-use emissions 1.9 Pg C/yrOceans -2.1 Pg C/yrAtmosphere -3.2 Pg C/yr
“The Missing Sink” 2.3 Pg C/yr
Houghton 2000 J. Geophys. Res. 105:20121-20130
Northern Hemisphere, Mid-latitude Forests: The Missing Sink?
• YES: Based on Atmospheric models that infer the combination of sources and sinks in atmospheric transport models that best match the global atmospheric CO2 data
• NO: Most land-based approaches using inventory data and ecosystem models have not been consistent with predictions, however, these studies have revealed significant heterogeneity in both space and time for terrestrial C pools and fluxes. These results have pointed to the need for more careful regional-scale analyses of C pools and fluxes.
• MAYBE (…Probably?…): Most recent results for the coterminous U.S. (Pacala et al. Science 292:2316) are consistent with the atmospheric studies, suggesting a net sink of 0.3-0.58 Pg C/yr (0.39-0.76 Mg C/ha/yr).
Regional-scale analyses are needed
• Analyses at the global and continental scale mask spatial and temporal heterogeneity in terrestrial C pools and fluxes
• An understanding of this heterogeneity is needed to narrow the remaining uncertainty in the global C budget.
• An understanding of this heterogeneity may reveal opportunities for management action that could increase C storage in terrestrial systems.
Land-use Impacts on PNW Forests
• PNW forests are among the most productive in the world.
• These forests have the capacity to store significant amounts of C
• Timber harvest activities in this region have the capacity to have a major impact on C flux.
Recent changes in harvest rates
0
2
4
6
8
10
1960 1970 1980 1990 2000
Year
Har
vest
Vo
lum
e (B
illio
ns
of
Bo
ard
F
eet
per
Yea
r)
TotalBLM + USFSIndustryOther
Or. Dept. Forestry Harvest Stats.
Westside Timber Harvest in Oregon
Disturbed Forest Carbon Model
Atmosphere
Onsite -Living -Detrital
Offsite -Forest Products
Harmon et al. 1990. Science 247:669
LANDCARB: A landscape-level carbon model
• Quantifying carbon dynamics at the landscape and regional scale requires the use of a model that captures the spatial and temporal complexities in terrestrial systems
• Satellite data can provide information on spatial and temporal heterogeneity
• A detailed stand-level model (STANDCARB) is used to parameterize a simplified “metamodel” that can be applied to individual grid cells corresponding to the ground resolution of the satellite imagery.
Carbon Storage following the disturbance of an old-growth stand
0
100
200
300
400
500
600
-50 50 150 250 350 450
Year
Car
bo
n S
tora
ge
(Mg
C/h
a)
Total
Live
Dead
Forest Products
Site Index 3
Overall Carbon flux from Western Oregon: 1972-95
A net SOURCE for 0.68 Mg C/ha/yr during 1972-95
Carbon Flux From Western Oregon: 1972-95
-2
-1
0
1
2
3
Year Intervals
C F
lux
(M
g C
/ha
/yr)
LiveDeadFor ProdTotal
Source to Atmosphere
Sink from Atmosphere
1972-77 1977-84 1984-88 1988-91 1991-95 1972-95
Range of variation in carbon flux
Total Carbon Flux from W. Oregon: 1972-95
0
5
10
15
20
25
30
35
-5 to -4 -4 to -2 -2 to -0.25
-0.25 to0.25
0.25 to2
2 to 4 4 to 8 8 to 14
Mg C / ha / yr
% o
f F
ore
st A
rea Sink from Atmosphere Source to Atmosphere
Model Validation
Total Harvest Volume (Tg C) 1972-95: Oregon Department of Forestry Records vs. LANDCARB Model Estimates. Each point represents a single county.
y = 0.80x - 0.17
0
10
20
30
40
0 5 10 15 20 25 30 35 40
Oregon Department of Forestry Records (Tg C)
LA
ND
CA
RB
Mo
de
l E
sti
ma
tes
(T
g C
)
Source for 0.68 Mg C/ha/yr
Sink for 1.24 Mg C/ha/yr
“What If” No timber harvests conducted from 1972-95?
Carbon Budget: Western Oregon, 1972-95
-4
-3
-2
-1
0
1
2
3
Year Intervals
Ca
rbo
n F
lux
(M
g/h
a/y
r)
Live
Dead
Offsite
Total
"What If" No timber harvest conducted from 1972-95
1972-77 1977-84 1984-88 1988-91 1991-95 1972-95
Source to Atmosphere
Sink from Atmosphere
A net SINK for 1.24 Mg C/ha/yr during 1972-95
Effect of Rotation Length on Carbon Storage
100
200
300
400
500
600
-50 50 150 250 350 450
Year
To
tal
C S
tora
ge
(M
g C
/ha
)
One harvest
100 Yr. rotation harvest
50 Yr. rotation harvestfirst harvest
Summary• Over the past 23 years, the forests of Western Oregon have been a net
source for 0.68 Mg C/ha/yr• Across the study area, C flux ranged from a sink of 4.7 to a source of
13.2 Mg C/ha/yr• This variability was related to land-use history, ownership and site
conditions• In the absence of timber harvesting between 1972 and 1995, this area
would have been a net sink for 1.24 Mg C/ha/yr• Our results demonstrate that timber harvesting has had a major impact
on the regional carbon budget and that changes in timber management practices could result in the sequestration of significant amounts of carbon in the region