Abstract
Vegetation changes in the Upper White Nile River (UWNR) are of great significance to the maintenance of local livelihoods, the survival of wildlife, and the protection of species habitats. Based on the GIMMS NDVI3g and MODIS normalized difference vegetation index (NDVI) data, the temporal and spatial characteristics of vegetation changes in the UWNR from 1982 to 2020 were analyzed by a Theil-Sen median trend analysis and Mann-Kendall test. The future trend of vegetation was analyzed by the Hurst exponential method. A partial correlation analysis was used to analyze the relationship of the vegetation and climate factors, and a residual trend analysis was used to quantify the influence of climate change and human activities on vegetation change. The results indicated that the average NDVI value (0.75) of the UWNR from 1982 to 2020 was relatively high. The average coefficient of variation for the NDVI was 0.059, and the vegetation change was relatively stable. The vegetation in the UWNR increased 0.013/10 year on average, but the vegetation degradation in some areas was serious and mainly classified as agricultural land. The results of a future trend analysis showed that the vegetation in the UWNR is mainly negatively sustainable, and 62.54% of the vegetation will degrade in the future. The NDVI of the UWNR was more affected by temperature than by precipitation, especially on agricultural land and forestland, which were more negatively affected by warming. Climate change and human activities have an impact on vegetation changes, but the spatial distributions of the effects differ. The relative impact of human activities on vegetation change accounted for 64.5%, which was higher than that of climate change (35.5%). Human activities, such as the large proportion of agriculture, rapid population growth and the rapid development of urbanization were the main driving forces. Establishing a cross-border drought joint early warning mechanism, strengthening basic agricultural research, and changing traditional agricultural farming patterns may be effective measures to address food security and climate change and improve vegetation in the UWNR.
Highlights
Licensee MDPI, Basel, Switzerland.As an important part of terrestrial ecosystems, vegetation is important in climate regulation, atmospheric composition regulation, water-energy-carbon exchange, and soil and water conservation; changes in vegetation will have a significant impact on the ecological environment [1,2,3,4]
I =1 where CV is the coefficient of variation of the normalized difference vegetation index (NDVI) value of each pixel on different time scales, σNDVI is the standard deviation of the NDVI value, NDVI is the average annual
Based on the MK mutation test results of the NDVI time series, the abrupt change in vegetation in the study area from 1982 to 2020 occurred in 1999, and the vegetation change trend could be roughly divided into two stages (Figure 4b)
Summary
As an important part of terrestrial ecosystems, vegetation is important in climate regulation, atmospheric composition regulation, water-energy-carbon exchange, and soil and water conservation; changes in vegetation will have a significant impact on the ecological environment [1,2,3,4]. Changes in vegetation can reflect changes in regional nature and human activities [9]. The effects of climate change and human activities on vegetation against the background of global change can provide a theoretical basis for ecosystem adaptability, which make it an important research topic in global change research and geography [10,11,12]. Climate is closely related to human activities, and it affect many major issues such as food, energy, population, vegetation and ecology. Human activities have a significant impact on the climate
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