Our paper, "A stepwise clustered ensemble temperature downscaling (SCETD) approach for assessing the future changes of temperature extremes over Yangtze River basin," has been accepted for publication in the Journal of Cleaner Production. This research introduces a new advanced statistical method to provide detailed insights into future temperature extremes in the Yangtze River basin, which is crucial for regional adaptation strategies.
We are pleased to announce the acceptance of our research, "A Stepwise Multifactor Regression Analysis of the Interactive Effects of Multiple Climate Factors on the Response of Vegetation Recovery to Drought," in the journal Atmosphere. This study employs a novel regression analysis to unravel the complex ways in which climate factors interact to influence how vegetation recovers from drought conditions.
Our latest work, "A stepwise-clustered copula downscaling approach for ensemble analyses of discrete and interactive features in precipitation-extreme variations: a case study for eastern China," has been accepted for publication in Climate Dynamics. This paper introduces a sophisticated statistical approach to analyze the intricate patterns and interactions within extreme precipitation events in eastern China, enhancing our understanding of regional climate risks.
Thrilled to share that our paper, "Interactions between anthropogenic greenhouse-gas and aerosol emissions will shape extreme precipitations over the Qinghai-Tibet Plateau," has been accepted by Geophysical Research Letters. This groundbreaking research reveals the significant and interactive roles of greenhouse gas and aerosol emissions from human activities in shaping the future of extreme precipitation events over the sensitive Qinghai-Tibet Plateau.
We're happy to announce the acceptance of our paper, "Multilevel Drought-Induced Resistance and Resilience Analysis for Vegetation in the Yellow River Basin," in Atmosphere. This comprehensive analysis investigates how vegetation in the Yellow River Basin resists and recovers from drought events, providing valuable insights for ecosystem management.
Our research, "Multilevel factorial analysis for effects of SSPs and GCMs on regional climate change: a case study for the Yangtze River Basin," has been accepted for publication in Climate Dynamics. This paper quantifies the contributions of different future socioeconomic pathways and global climate models to regional climate change projections in the Yangtze River Basin.
Our paper, "Projections of compound wet-warm and dry-warm extreme events in summer over China," has been accepted for publication in the Journal of Hydrology. This study provides crucial projections of the co-occurrence of wet-warm and dry-warm extreme events during summer across China, highlighting potential risks to public health and agriculture.
We are excited to share that our research, "Quantile delta-mapped spatial disaggregation analysis for climate variations over the Yangtze River Basin," has been accepted by the Journal of Applied Meteorology and Climatology. This paper presents a new advanced statistical technique to provide detailed, spatially refined analysis of climate variations across the Yangtze River Basin.
Our paper, "Quantile delta-mapped spatial disaggregation analysis for summertime compound extremes over China," has been accepted for publication in Climate Dynamics. This work offers a detailed spatial analysis of compound climate extremes occurring in summertime over China, utilizing a sophisticated statistical method.
We're pleased to announce the acceptance of our study, "Spatiotemporal geographically weighted regression analysis for runoff variations in the Weihe River Basin," in the Journal of Environmental Management. This research uses advanced spatial statistics to analyze the changing patterns of runoff in the Weihe River Basin over time, identifying key influencing factors.
Our research, "The increasing water stress projected for China could shift the agriculture and manufacturing industry geographically," has been accepted for publication in Communications Earth & Environment. This paper highlights the potential for increasing water stress across China to lead to substantial geographical shifts in the agriculture and manufacturing sectors.