Abstract
AbstractLand Surface Albedo (LSA) of forested environments continues to be a source of uncertainty in land surface modeling, especially across seasonally snow covered domains. Assessment and improvement of global scale model performance has been hampered by the contrasting spatial scales of model resolution and in‐situ LSA measurements. In this study, point‐scale simulations of the Community Land Model 5.0 (CLM5) were evaluated across a large range of forest structures and solar angles at two climatically different locations. LSA measurements, using an uncrewed aerial vehicle with up and down‐looking shortwave radiation sensors, showed canopy structural shading of the snow surface exerted a primary control on LSA. Diurnal patterns of measured LSA revealed strong effects of both azimuth and zenith angles, neither of which were adequately represented in simulations. In sparse forest environments, LSA were overestimated by up to 66%. Further analysis revealed a lack of correlation between Plant Area Index (PAI), the primary canopy descriptor in CLM5, and measured LSA. Instead, measured LSA showed considerable correlation with the fraction of snow visible in the sensor's field of view, a correlation which increased further when only considering the sunlit fraction of visible snow. The use of effective PAI values as a simple first‐order correction for the discrepancy between measured and simulated LSA in sparse forest environments substantially improved model results (64%–76% RMSE reduction). However, the large biases suggest the need for a more generic solution, for example, by introducing a canopy metric that represents canopy gap fraction rather than assuming a spatially homogeneous canopy.
Highlights
Land Surface Albedo (LSA), defined as the fraction of incoming shortwave radiation that is reflected by the surface of the Earth (Dickinson, 1983), is considered an essential climate variable (GCOS, 2016)
An extensive data set of airborne LSA measurements using an uncrewed aerial vehicle (UAV) co-registered to canopy structure and snow surface shading information, captured a large range of canopy structures and solar angles in subalpine (Switzerland) and boreal (Finland) locations
Measurements revealed a strong correlation between LSA and sunlit-snow across a range of tree species, solar angles, and canopy structures, further emphasizing the dominant control canopy structural shading has over LSA
Summary
Land Surface Albedo (LSA), defined as the fraction of incoming shortwave radiation that is reflected by the surface of the Earth (Dickinson, 1983), is considered an essential climate variable (GCOS, 2016). Complex vegetation-snow-albedo interactions continue to be a source of uncertainty in land surface models (LSMs), with large biases across boreal evergreen forests (Loranty et al, 2014; Thackeray et al, 2019). Given the global warming-induced reduction in snow cover extent (Derksen & Brown, 2012; Kunkel et al, 2016) and the interrelated implications on water resources (Barnett et al, 2005; Sturm et al, 2017), agriculture (Qin et al, 2020), carbon balance (Pulliainen et al, 2017) and LSA itself (Zhang et al, 2019), it is paramount to reduce such uncertainties in LSMs
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