Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
11021794 | Ecological Modelling | 2018 | 8 Pages |
Abstract
Accurate predictions of water vapor at large temporal and spatial scales are particularly important in global studies. In recent years, Central Asian grasslands have been subject to both intensive grazing and variability in climatic conditions. However, uncertainties about grazing on water cycling under climate change still exist. Therefore, the Biome-BGC grazing model was applied to assess the effects of grazing on evapotranspiration (ET) and water use efficiency (WUE). Three grassland types were studied during the period 1979-2011: forest meadow (FM), temperate grassland (TG) and desert grassland (DG). ET shows a gradual decreasing trend from FM (365.65â±â36.86âmm mâ2 yrâ1) to DG (183.32â±â21.15âmm mâ2 yrâ1), and WUE ranging from 0.62â±â0.03âg C kg-1 H2O in FM to 1.12â±â0.10âg C kgâ1 H2O in TG, with an average of 0.83â±â0.05âg C kgâ1 H2O. Although there was a significant decrease in ET of 1.47-2.72âmm mâ2 yrâ1, WUE increased at a rate of 0.004âg C kgâ1 H2O yrâ1 in Central Asia. From 1979 to 2011, grazing lowered ET by 7.47% in Central Asia; the reduction rates for FM, TG and DG were 3.10%, 12.70% and 7.42%, respectively. In general, grazing decreased WUE by 3.60%. From non-grazed to grazed scenario, WUE increased by 6.86% for FM, but WUE decreased by 7.27% and 5.61% for TG and DG. An over-compensation of GPP under grazing might account for the higher WUE under certain grazing intensities. In order to achieve maximum utilization of water efficiency, proper grazing intensity for TG, DG and FM should be limited to 0.17, 0.39 and 0.38 head/ha, respectively.
Related Topics
Life Sciences
Agricultural and Biological Sciences
Ecology, Evolution, Behavior and Systematics
Authors
Qifei Han, Chaofan Li, Chengyi Zhao, Yaoqi Zhang, Shoubo Li,