Abstract
This study was conducted using daily precipitation records gathered at 37 meteorological stations in northern Xinjiang, China, from 1961 to 2010. We used the extreme value theory model, generalized extreme value (GEV) and generalized Pareto distribution (GPD), statistical distribution function to fit outputs of precipitation extremes with different return periods to estimate risks of precipitation extremes and diagnose aridity–humidity environmental variation and corresponding spatial patterns in northern Xinjiang. Spatiotemporal patterns of daily maximum precipitation showed that aridity–humidity conditions of northern Xinjiang could be well represented by the return periods of the precipitation data. Indices of daily maximum precipitation were effective in the prediction of floods in the study area. By analyzing future projections of daily maximum precipitation (2, 5, 10, 30, 50, and 100 years), we conclude that the flood risk will gradually increase in northern Xinjiang. GEV extreme value modeling yielded the best results, proving to be extremely valuable. Through example analysis for extreme precipitation models, the GEV statistical model was superior in terms of favorable analog extreme precipitation. The GPD model calculation results reflect annual precipitation. For most of the estimated sites’ 2 and 5-year T for precipitation levels, GPD results were slightly greater than GEV results. The study found that extreme precipitation reaching a certain limit value level will cause a flood disaster. Therefore, predicting future extreme precipitation may aid warnings of flood disaster. A suitable policy concerning effective water resource management is thus urgently required.
Highlights
Climate change, characterized by global warming and its effect on human society, affects the spatiotemporal characteristics of precipitation and increases the frequency of extreme events, such as floods and droughts (Vörösmarty et al 2010)
We applied generalized extreme value (GEV) and generalized Pareto distribution (GPD) statistical distribution functions to fit the output of precipitation extremes with different T, to diagnose the risk of flood variability and associated spatial patterns in northern Xinjiang, China
Through example analysis for extreme precipitation models, the GEV statistical model was superior for favorable analog extreme precipitation
Summary
Climate change, characterized by global warming and its effect on human society, affects the spatiotemporal characteristics of precipitation and increases the frequency of extreme events, such as floods and droughts (Vörösmarty et al 2010). Zhang et al (2015) showed that indices representing temporal variations of regional heavy precipitation display strong inter-decadal variability, with limited evidence of long-term trends. Li et al (2011) indicated that flood disasters have increased in response to the higher frequency of intense precipitation events and consequent amplification of their concentration indices and precipitation concentration. Such indicators vary markedly depending on precipitation type, season, and region. The extreme precipitation in the northern region is used as a research example to show that risk analysis of extreme precipitation can improve the future diagnosis of flood risk, variability, and spatial pattern in Xinjiang, China. It is hoped that the results of this study can provide reference points for global climate change and provide some decisionmaking value for the prevention of disasters caused by extreme climate events
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