Ximeng Xu scite author profile

Investigation of the pressing impacts of climate change on drought is vital for sustainable societal and ecosystem functioning. The magnitude of how much the drought will change and the way how droughts would affect society and the environment are inadequately addressed over East Africa. This study aimed at assessing future drought changes using an ensemble of five Global Climate Models (GCMs) in the Coupled Model Intercomparison Project (CMIP5) over East Africa. To this end, drought characteristics were investigated under the Representative Concentration Pathways (RCPs) 2.6, 4.5, and 8.5 in the near term (the 2020s; 2011–2040), midcentury (2050s; 2041–2070), and end of century (2080s; 2071–2,100). The changes of the Standardized Precipitation Index (SPI) and Standardized Precipitation‐Evapotranspiration Index (SPEI) were first compared, and the SPEI was used for measuring future droughts as it showed stronger changes due to its inclusion of temperature effects. Drought area in East Africa is likely to increase at the end of the 21st century by 16%, 36%, and 54% under RCP 2.6, 4.5, and 8.5, respectively, with the areas affected by extreme drought increasing more rapidly than severe and moderate droughts. Spatially, drought event, duration, frequency and intensity would increase in Sudan, Tanzania, Somalia, and South Sudan, but generally decrease in Kenya, Uganda, and Ethiopian highlands. Results also confirm that drought changes over East Africa follow the “dry gets drier and wet gets wetter” paradigm. The findings provide important guidance for improving identification of causes, minimizing the impacts and enhancing the resilience to droughts in East Africa.

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Comparison of runoff and soil loss in different tillage systems in the Mollisol region of Northeast China

Zheng

Wilson

et al. 2018

Soil and Tillage Research

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A portable and cost-effective microfluidic system for massively parallel single-cell transcriptome profiling

Fan

et al. 2019

Preprint

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29Single-cell technologies are becoming increasingly widespread and have been 30 revolutionizing our understanding of cell identity, state, diversity and function. However, 31 current platforms can be slow to apply to large-scale studies and resource-limited 32 clinical arenas due to a variety of reasons including cost, infrastructure, sample quality and requirements. Here we report DNBelab C4 (C4), a negative pressure orchestrated, 1 portable and cost-effective device that enables high-throughput single-cell 2 transcriptional profiling. C4 system can efficiently allow discrimination of species-3 specific cells at high resolution and dissect tissue heterogeneity in different organs, 4 such as murine lung and cerebral cortex. Finally, we show that the C4 system is 5 comparable to existing platforms but has huge benefits in cost and portability and, as 6 such, it will be of great interest for the wider scientific community. 7 8

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Ximeng Xu

Projected Impacts of Climate Change on Drought Patterns Over East Africa

Comparison of runoff and soil loss in different tillage systems in the Mollisol region of Northeast China

A portable and cost-effective microfluidic system for massively parallel single-cell transcriptome profiling

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