Abstract
Abstract. Topography exerts significant influences on the incoming
solar radiation at the land surface. A few stand-alone regional and global
atmospheric models have included parameterizations for sub-grid topographic
effects on solar radiation. However, nearly all Earth system models (ESMs)
that participated in the Coupled Model Intercomparison Project (CMIP6) use a plane-parallel (PP) radiative transfer scheme that assumes that the terrain is
flat. In this study, we incorporated a well-validated sub-grid topographic
(TOP) parameterization in the Energy Exascale Earth System Model (E3SM) Land
Model (ELM) version 1.0 to quantify the effects of sub-grid topography on
solar radiation flux, including the shadow effects and multi-scattering
between adjacent terrain. We studied the role of sub-grid topography by
performing ELM simulations with the PP and TOP schemes over the Tibetan
Plateau (TP). Additional ELM simulations were performed at multiple spatial
resolutions to investigate the role of spatial scale on sub-grid topographic effects on solar radiation. The Moderate Resolution Imaging
Spectroradiometer (MODIS) data was used to compare with the ELM simulations.
The results show that topography has non-negligible effects on surface
energy budget, snow cover, snow depth, and surface temperature over the TP.
The absolute differences in surface energy fluxes for net solar radiation,
latent heat flux, and sensible heat flux between TOP and PP exceed 20, 10, and 5 W m−2, respectively. The differences in land surface albedo, snow cover fraction, snow depth, and surface temperature between TOP and PP exceed 0.1, 0.1, 10 cm, and 1 K, respectively. The magnitude of the sub-grid topographic effects is dependent on seasons and elevations and is also sensitive to the spatial scales. Although the sub-grid topographic effects on solar radiation are larger with more spatial details at finer spatial scales, they cannot be simply neglected at coarse spatial scales. When compared to MODIS data,
incorporating the sub-grid topographic effects overall reduces the biases of ELM in simulating surface energy balance, snow cover, and surface temperature, especially in the high-elevation and snow-covered regions over the TP. The inclusion of sub-grid topographic effects on solar radiation
parameterization in ELM will contribute to advancing our understanding of
the role of the surface topography on terrestrial processes over complex
terrain.
Funder
National Science Foundation
Office of Science
National Oceanic and Atmospheric Administration
Cited by
47 articles.
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