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Can Topographic Effects on Solar Radiation Be Ignored: Evidence From the Tibetan Plateau

Authors :
Xian, Yuyang
Wang, Tianxing
Leng, Wanchun
Letu, Husi
Shi, Jiancheng
Wang, Gaofeng
Yan, Xuewei
Yuan, Hongyin
Source :
Geophysical Research Letters; March 2024, Vol. 51 Issue: 6
Publication Year :
2024

Abstract

The effect of topography on shortwave downward radiation (SWDR) is interest in the geoscience. However, such effects are rarely quantiatively and systematically evalulated, especially over the Tibetan Plateau region. With the geostationaly satellite measurements and topographic radiation model, this study reveals a heightened significance of topography on SWDR with increasing slope. Particularly in abrupt terrain (slopes >15°) the impact becomes pronounced, wherein the topographic radiative forcing (TRF) contributes 9.5% of the annual‐average SWDR. And the ratio of TRF to SWDR reaches a peak during winter, exceeding 150%. In annual‐average scales, the SWDR is 169 ± 38.4 W/m2and the corresponding TRF is 16.2 ± 22.6 W/m2. Seasonal variations manifest on northern and southern slopes, with the sourthern slopes significant in summer, while the northern ones significant in winter. Notably, topographic effects persist across spatial scales and remain evident at 5 km resolution, emphasizing the necessity of considering topography in SWDR product utilization. Shortwave downward radiation is the main source of surface energy. In mountainous areas, the terrain significantly alters the amount of received SWDR. This study comrephensively examines the topographic influence on SWDR across the Tibetan Plateau for the first time. We investigate the influence of diverse topographic factors on the distribution of surface shortwave radiation in mountainous terrains. With the slope increasing, the impact of topography on SWDR becomes more and more significant. The topographic impact of northern and sourthern slopes behaves obvious seasonal variations, with the sourthern slopes significant in summer, while the northern ones significant in winter. With the increasing of spatial scale, the topographic effect gradually decreases and tends to be stable, but it can never disappear. As remote sensing data resolution coarsens, topographic radiative forcing diminishes, but even at 5 km resolution, terrain significantly affects SWDR distribution. In abrupt slopes, the annual‐average proportion of topographic radiative forcing to shortwave downward radiation (SWDR) can reach up to 9.5%The proportion of topographic radiative forcing to SWDR exceeding 150% in winter on the northern slopesDespite decreasing influence with coarser spatial resolutions, topographic effects persist even at 5 km In abrupt slopes, the annual‐average proportion of topographic radiative forcing to shortwave downward radiation (SWDR) can reach up to 9.5% The proportion of topographic radiative forcing to SWDR exceeding 150% in winter on the northern slopes Despite decreasing influence with coarser spatial resolutions, topographic effects persist even at 5 km

Details

Language :
English
ISSN :
00948276
Volume :
51
Issue :
6
Database :
Supplemental Index
Journal :
Geophysical Research Letters
Publication Type :
Periodical
Accession number :
ejs65883935
Full Text :
https://doi.org/10.1029/2024GL108653