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Testing and development of the Canadian land surface scheme (class) for forests, agricultural crops and bare soils

University of British Columbia

CLASS (Canadian Land Surface Scheme) is the land surface model currently used in the Canadian general circulation model. It features a single vegetation layer, three soil layers (and a snow layer when necessary) and physically-based calculations of the energy and water exchange between the atmosphere and land surface. This research focused on the validation of CLASS and the improvement of relevant parameterizations. CLASS was tested using continuous half-hourly energy balance and soil water content (θ) data collected during much of 1994 and from spring 1996 to the end of 1998 from a boreal aspen forest and during short summer periods over past 20 years from six west coast Douglas-fir forests, two agricultural crops and two bare soils. Tests identified the following deficiencies in CLASS : (1) evaporation from the soil surface was significantly overestimated, (2) transpiration from the aspen forest was underestimated under conditions of high solar irradiance, (3) winter albedo was too high, and (4) surface runoff after snowmelt was excessive. Two semi-empirical soil evaporation relationships (the α and β methods) were compared with Philip's relationship using measurements of evaporation from a bare loam/silt-loam soil. The latter, although physically-based, performed poorly when used with a thick surface soil layer as in CLASS. The β method performed significantly better than the a method. Parameterizations of canopy conductance (g[sub c]) based on the Jarvis- Stewart (JS) (also used in CLASS), the Ball-Woodrow-Berry (BWB) and a modified form of the BWB parameterization (MBWB) were evaluated for the aspen forest and a Douglas-fir forest. A new JS parameterization gave the best estimates of g[sub c], while the MBWB parameterization performed better than the BWB parameterization. The new JS and MBWB parameterizations worked well for five Douglas-fir forests of similar age with different leaf area indices under conditions of high θ but worked poorly for conditions of low θ because the response of Douglas-fir g[sub c] to soil water stress differed considerably from site to site. Adjusting the winter albedo for the aspen forest from 0.5 to the more realistic value of 0.25 significantly improved the calculation of winter net radiation, predicted the occurrence of snowmelt only 5-10 days later than observations and significantly reduced the overestimation of surface runoff following snowmelt. The near-field effect on flux calculations was examined using two approaches: (1) the near-field resistance was places in series with the aerodynamic resistance in CLASS, and (2) the performance of a Lagrangian two-layer canopy model was compared with a Ktheory two-layer canopy model and a /f-theory single-layer canopy model. The first approach was tested using data from a Douglas-fir forest, the aspen forest and an agricultural crop. The second approach was tested using data from the aspen forest because it had a thick understory canopy. Results from both approaches confirmed that the difference between simulations from AT-theory and the Lagrangian evaporation models was small due to the strong control by stomatal conductance. Furthermore, the two-layer canopy models were inferior to the single-layer canopy model in the calculation of the sensible and latent heat fluxes above the forest.

Thesis/Dissertation

application/pdf

2009-07-03

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http://hdl.handle.net/2429/10144

Soil Science

University of British Columbia

UBCV

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