Use of intensity analysis and transfer matrix to characterize land conversion in the Aral Sea Basin under changing climate

An effective approach to identifying the size and intensity of land transitions is vital for land use and management decisions. This study used a transfer matrix and intensity analysis to quantify the land conversion from 1995 to 2015 in the Aral Sea Basin (ASB). The analysis is based on annual land...

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Bibliographic Details
Published in:Modeling earth systems and environment 2024-08, Vol.10 (4), p.4717-4729
Main Authors: Berdimbetov, Timur, Shelton, Sherly, Pushpawela, Buddhi, Rathnayake, Upaka, Koshim, Asyma G., Yegizbayeva, Asset, Nietullaeva, Sahibjamal
Format: Article
Language:English
Subjects:
Agricultural land
Barren lands
Chemistry and Earth Sciences
Climate change
Climate models
Computer Science
Data analysis
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Ecosystems
Environment
Land cover
Land resources
Land use
Land use management
Math. Appl. in Environmental Science
Mathematical Applications in the Physical Sciences
Mitigation
Original Article
Physics
Statistics for Engineering
Sustainable development
Transfer matrices
Urban areas
Vegetation index
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Summary:An effective approach to identifying the size and intensity of land transitions is vital for land use and management decisions. This study used a transfer matrix and intensity analysis to quantify the land conversion from 1995 to 2015 in the Aral Sea Basin (ASB). The analysis is based on annual land cover data from the European Space Agency Climate Change Initiative and normalized density vegetation index data from Global Inventory Modelling and Mapping Studies (GIMMS). According to our analysis, 42.39% of the total land area of ASB is covered by bareland (762,300 km 2 ). Due to the most extensive transition intensity from water to bareland, it expanded gradually by 6,100 km 2 during the 1995 to 2015 period. Furthermore, we found expanding cropland and urban area, where the urban area continuously expanded from 12,000 to 61,700 km 2 during 20-year periods. In contrast, forest and water areas decreased continuously, where the forest (70,900 km 2 ) and water area 67,900 km 2 ) decreased by 0.12% and 3.77%, respectively. Interestingly, we found that the loss of forests contributed to the cropland and urban areas’s gain while water bodies were transformed into barren and shrubland areas and, further, developed into deserts. This study enriches the methodology of intensity analysis and provides a scientific reference for the adaptation, mitigation, and sustainable development and management of land resources in ASB.
ISSN:2363-6203
2363-6211
DOI:10.1007/s40808-024-02019-x