Abstract
In this paper, the coupled WRF/SSiB model, accompanied by a Karst Rocky Desertification (KRD) map of the Guizhou Karst Plateau (GKP) of China, was applied to detect how the changed vegetation and soil characteristics over the GKP modify the energy balance at the land surface. The results indicated that land degradation led to reduced net radiation by inducing more upward shortwave and longwave radiation, which were associated with increasing surface albedo and temperature, respectively. The KRD also resulted in changed surface energy partitioning into sensible and latent heat fluxes. The latent heat flux at land surface was reduced substantially due to the higher surface albedo and stomatal resistance, the lower Leaf Area Index (LAI) and roughness length in the degradation experiment, while the sensible heat flux increased, mainly because of the higher surface temperature. Furthermore, the moisture flux convergence was reduced, owing to the lower atmospheric heating and the relative subsidence. However, compared with the reduced evaporation, the decrease in moisture flux convergence contributed much less to the reduced precipitation. Precipitation strongly affects soil moisture, vegetation growth and phenology, and thus evaporation and convective latent heating, so when precipitation was changed, a feedback loop was created.
Highlights
During the past decades, the vegetation-climate interaction has been a focus of meteorology, climatology, geography and ecology studies
It is recognized that the final quality of the results from regional climate model (RCM) depends in part on the reality of the large-scale forcing provided by reanalyses
This study indicated that the effects of Karst Rocky Desertification (KRD) over the Guizhou Karst Plateau (GKP) can significantly influence the regional climate by modifying the energy budget at the land surface
Summary
The vegetation-climate interaction has been a focus of meteorology, climatology, geography and ecology studies. 1950s, Karst Rocky Desertification (KRD), defined as the transformation of vegetation and soil covered Karst landscape to exposed basement rocks [20], affects over 20% of the total area with a desertification rate of 2.5 × 104 km per year [21], and has become the most serious environmental problem in the GKP. Based on both satellite images and field observation over GKP, Xiong et al [22].
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