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Assessing spatio-temporal variations of precipitation-use efficiency over Tibetan grasslands using MODIS and in-situ observations

Liu, Zhengjia, Huang, Mei
Frontiers of earth science 2016 v.10 no.4 pp. 784-793
alpine meadows, altitude, atmospheric precipitation, carbon, ecosystems, hydrologic cycle, models, moderate resolution imaging spectroradiometer, normalized difference vegetation index, primary productivity, remote sensing, sea level, steppes, temporal variation, China
Clarifying the spatial and temporal variations in precipitation-use efficiency (PUE) is helpful for advancing our knowledge of carbon and water cycles in Tibetan grassland ecosystems. Here we use an integrated remote sensing normalized difference vegetation index (NDVI) and in-situ above-ground net primary production (ANPP) measurements to establish an empirical exponential model to estimate spatial ANPP across the entire Tibetan Plateau. The spatial and temporal variations in PUE (the ratio of ANPP to mean annual precipitation (MAP)), as well as the relationships between PUE and other controls, were then investigated during the 2001–2012 study period. At a regional scale, PUE increased from west to east. PUE anomalies increased significantly (>0.1 g·m–²·mm–¹/10 yr) in the southern areas of the Tibetan Plateau yet decreased (>0.02 g·m–²·mm–¹/10 yr) in the northeastern areas. For alpine meadow, we obtained an obvious breaking point in trend of PUE against elevation gradients at 3600 m above the sea level, which showed a contrasting relationship. At the inter-annual scale, PUE anomalies were smaller in alpine steppe than in alpine meadow. The results show that PUE of Tibetan grasslands is generally high in dry years and low in wet years.