Abstract

Leaf optical properties (LOPs, i.e., leaf reflectance and transmittance), as a fundamental property of vegetation, are a key parameter in the canopy radiative transfer process. LOPs have a direct impact on the surface solar radiation partition and further affect surface flux exchanges. Recent works have provided reliable LOP data and mentioned that notable differences exist between the prescribed LOP values in current land surface models and measured LOP values, especially in the near-infrared (NIR) band. To evaluate the effects of different LOP values in land surface modeling, we ran two land surface models (the Community Land Model and the Common Land Model) with their default prescribed and measured values to examine the differences in simulated surface radiation partitions and fluxes. Our analyses show that differences in LOP values can lead to a large discrepancy in albedo, radiation partition, sensible heat flux and net radiation simulations. By using the measured LOP values, in the boreal forest zone, Southeast China, and the eastern United States, both models have a significantly increased surface albedo in the NIR band, with the difference exceeding 10% during JJA. Thus, the measured LOP values can improve the negative albedo bias in the boreal forest zone during summertime. Moreover, both models simulate less net radiation with a maximum reduction of 11 W/m2 when incorporating the measured LOP values. Therefore, the total sensible heat flux can be reduced by as much as 11 W/m2. The results of this study emphasize that different LOP values can have a considerable effect on the surface radiation budget and sensible heat flux simulations which need attention in land surface model development. However, in current offline simulations, the measured LOP values cause slight changes in land surface temperatures and gross primary productivity (GPP).

Highlights

  • Leaf optical properties (LOPs, i.e., leaf reflectance and transmittance) are among the most important driving factors of the Earth’s surface energy balance

  • The results indicate that the measured LOP values have a significant effect on surface albedo simulation, radiation partitioning and SH exchange in the boreal forest zone, Southeast China and the eastern United States

  • The negative bias of surface albedo between the model and observational data can be significantly improved in the boreal forest zone during JJA

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Summary

Introduction

Leaf optical properties (LOPs, i.e., leaf reflectance and transmittance) are among the most important driving factors of the Earth’s surface energy balance. Leaf Optical Property of the crucial parameters in the land surface radiation budget and energy balance (Zhai et al, 2014). Many kinds of studies show that albedo plays an important role in land surface temperature change (Dickinson and Henderson-Sellers, 1988; Bounoua et al, 2002; Holland and Bitz, 2003; Winton, 2006) and has a significant effect on rainfall (Xue and Shukla, 1993; Dirmeyer and Shukla, 1996; Knorr et al, 2001; Levine and Boos, 2017). Surface albedo shapes the Earth’s climate and climate change (Soden and Held, 2006; Randall et al, 2007)

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