Abstract
Drought is one of the most complex and least-understood environmental disasters that can trigger environmental, societal, and economic problems. To accurately assess the drought conditions in the Yellow River Basin, this study reconstructed the Land Surface Temperature (LST) using the Annual Temperature Cycle (ATC) model and the Normalized Difference Vegetation Index (NDVI). The Temperature Condition Index (TCI), Vegetation Condition Index (VCI), Vegetation Health Index (VHI), and Temperature-Vegetation Drought Index (TVDI), which are four typical remote sensing drought indices, were calculated. Then, the air temperature, precipitation, and soil moisture data were used to evaluate the applicability of each drought index to different land types. Finally, this study characterized the spatial and temporal patterns of drought in the Yellow River Basin from 2003 to 2019. The results show that: (1) Using the LST reconstructed by the ATC model to calculate the drought index can effectively improve the accuracy of drought monitoring. In most areas, the reconstructed TCI, VHI, and TVDI are more reliable for monitoring drought conditions than the unreconstructed VCI. (2) The four drought indices (TCI, VCI, VH, TVDI) represent the same temporal and spatial patterns throughout the study area. However, in some small areas, the temporal and spatial patterns represented by different drought indices are different. (3) In the Yellow River Basin, the drought level is highest in the northwest and lowest in the southwest and southeast. The dry conditions in the Yellow River Basin were stable from 2003 to 2019. The results in this paper provide a basis for better understanding and evaluating the drought conditions in the Yellow River Basin and can guide water resources management, agricultural production, and ecological protection of this area.
Highlights
Drought is an extremely complex natural disaster, and the occurrence of drought leads to decreased agricultural productivity [1], land desertification, and forest degradation, among other social environmental problems [2,3,4]
These results show that the drought index calculated using the Annual Temperature Cycle (ATC) Land Surface Temperature (LST) data shows severer drought conditions compared to the drought index calculated by the original MODIS LST data, which facilitates the identification of mild drought
The results show that the drought indexes of Temperature Condition Index (TCI), Vegetation Health Index (VHI), and Temperature-Vegetation Drought Index (TVDI) found through the ATC model are related to precipitation, temperature, and soil moisture, which fully reflects the necessity of data reconstruction methods in drought monitoring research
Summary
Drought is an extremely complex natural disaster, and the occurrence of drought leads to decreased agricultural productivity [1], land desertification, and forest degradation, among other social environmental problems [2,3,4]. 2021, 13, 3748 decades, global environmental and climate change has caused changes in the water cycle; population growth and increased agricultural and industrial water use have further exacerbated water shortages [7,8]. This leads to the increasing frequency of drought events [9,10,11,12,13,14,15]. The commonly used drought monitoring method is based on the observation data from meteorological stations, and it calculates a drought index
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