Post on 12-Jan-2016
Guo-Yue Niu and Zong-Liang Yang
The Department of Geological Sciences
The University of Texas at Austin
Evaluation of snow simulations Evaluation of snow simulations from CAM2/CLM2.0from CAM2/CLM2.0
Research was funded under NASA grant NAG5-12577
OutlineOutline
Brief Introduction of Snow-related Schemes Snowfall Snowpack physics Snow albedo Snow cover fraction
Evaluation of Wintertime Surface Albedo and Snow Depth Wintertime surface albedo and snow depth Main factors affecting wintertime surface albedo Sensitivity studies
A new Snow Cover Fraction Scheme Evaluation of Snowfall Summary and Future work
Introduction
1. Over the past century, the largest global warming has occurred in the high latitude areas (Houghton et al, 2001)
2. The CAM2/CLM2 produced a significant warm bias in snow-covered regions during wintertime
3. The goal of this study is to investigate how this warm bias is related to the representation of snow processes in CAM2/CLM2
Snow-related Parameterization Schemes inCAM2/CLM2 in Comparison with CCM3/LSM1.0
CCM3/LSM CAM2/CLM2
Snowfall
Snowpack Physics
Snow Albedo
SCF
Ts<Tfrz+2.0 T(b3)<Tfrz–2.0
1-L No Liquid water No densification
5-L Liquid water Densification
Marshall (1989) BATS
LSM1.0 BATS
Consequences in SWE
–
+ +
+
– – –
Snow Cover Fraction Schemes
Two 12-year Experiments: 1. Control run with default
SCF scheme
2. Modified run with the Yang et al. (1997) SCF scheme
Yang et al (1997) scheme has been tested by Roesch et al (2000) at T106.
Applicable to flat, non-forested areas.
Wintertime Surface Albedo (FEB)
MODIS
CLM2/Yang
CLM2/ Default
CLM2/default produced higher surface albedo in boreal forest regions, lower surface albedo in mid-latitude regions. However, CLM2/Yang improved the surface albedo simulations in mid-latitude regions.
Wintertime Surface Albedo – regional averages
Mid-latitude grass/cropland Regions
Boreal Forest Regions
OBS
Default
Yang
Snow Depth – regional averages
Mid-latitude grass/cropland Regions
Boreal Forest Regions
OBS
Default
Yang
Factors Affecting Wintertime Land Surface Albedo
Vegetation shading factors Tree cover fraction Leaf/stem area index Vegetation height (canopy fraction buried by snow)
Snow on canopy Tree cover fraction Interception capacity Meteorological conditions (wind, temperature)
Ground snow covered fraction (SCF) Ground surface roughness length Snow depth
Snow properties Grain radius Impurity
The model prescribed tree (needleleaf & broadleaf) cover fraction from the 1-km IGBP DISCover dataset and the 1-km University of Maryland tree cover dataset (Bonan et al, 2002)
The tree cover fraction is between 40-60% meaning a significant fraction of open areas for potentially high surface albedo.
Tree Cover Fraction in CAM2/CLM2
The modeled effective leaf area index (after buried by snow) is higher than the AVHRR values, especially in boreal forest regions.
LAI & SAI in CAM2/CLM2 (February)
AVHRR
CAM2/CLM2
CCM3/LSM
Over 80 percent of canopy is buried by snow in the high latitude tundra areas.
Fraction of Canopy Buried by Snow in CAM2/CLM2
Four 1-month Sensitivity Experiments
Mid-latitude grass/cropland Regions
Boreal Forest Regions
default: CAM2/CLM2 default runrun1: No snow effects on canopy albedorun2: Yang et al. (1997) SCF schemerun3: Doubling LAI & SAI
Spectral-integrated albedo as function of (LAI+SAI)
Surface Air Temperature (February)
The significant warm bias both in Eurasia and North America from the default CAM2/CLM2 is largely reduced by using the Yang et al (1997) SCF scheme
CLM2/Yang – OBS
CLM2/Default – OBS
Regional Averaged Snow Depth
Yang et al (1997) SCF scheme produced too much snow and a cold bias in melting season
Mid-latitude grass/cropland Regions
Boreal Forest Regions
Eurasia North America
Observed Depletion Curve in Melting Season in a Small WatershedF
ract
iona
l Sno
w C
over
ed A
rea
Basin Avg. SWE / Maximum Basin Avg. SWE
Upper Sheep Creek Watershed, Idaho (26 ha)
From Luce & Tarboton (1999)
A New Snow Cover Fraction
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)5.2
tanh(
2
max
0
h
h
z
h
SCFsno
g
sno
daymmq
daymmq
melt
melt
/3
/3
Need further validation with high resolution snow cover and snow depth data
Wintertime Surface Air Temperature
Default-OBS (DJF)
NEW-OBS (DJF)
Melting Season Surface Air Temperature
Default-OBS (MAM)
NEW-OBS (MAM)
Regional Averaged Snow Depth
Mid-latitude Grass/cropland Regions
Boreal Forest Regions
Eurasia North America
Improved simulations of snow depth in mid-latitude areas
Snowfall Estimation using Monthly T and Prec Observations
)15.273(35.1*6.11
1
*Pr
TR
RecSnowfallLegates & Willmott (1990)
Evaluation of Snowfall (MAM)
Global Air Temperature and Precipitation (V. 2.01) (Willmott and Matsuura, 1995)
CAM2-CCM3
CCM3-OBS
CAM2-OBS
Regional Averages of Snowfall
Europe
North AmericaEurasia
Northwest NA
CAM2/CLM2 improved the snowfall simulations in fall and spring seasons compared to CCM3/LSM, but underestimated snowfall in winter season.
Ongoing Work
Using high resolution datasets of snow cover, land surface albedo and snow depth
To analyze the relationship between SCF and snow depth
To analyze the relationship between SCF and seasons
To analyze the relationship between SCF and sub-grid topography
To parameterize SCF as function of snow depth, canopy height (land cover), season, and sub-grid topography
Funded by a 3-year NASA grant
Summary
• The snow simulations have been assessed using observed climatology of snow depth, temperature and MODIS-derived surface albedo.
• The CAM2/CLM2 produced shallower than observed snow depth and lower surface albedo, which coincide with a warm bias in mid-latitude regions in wintertime.
• The shallower snow depth and lower surface albedo may be largely due to an inappropriate SCF parameterization scheme.
• A new SCF scheme, which differentiates snow cover patterns during accumulation and melt periods, improves the simulations of snow depth, surface albedo, and surface air temperature.
• CAM2/CLM2 improved snowfall simulations in fall and spring seasons compared to CCM3/LSM, but underestimated snowfall in winter season.