Insight into the drivers and interactions in the evolution of low-lying river network patterns in the Jianghuai plains, China.

The Jianghuai plains, formed by the deposits of the Yangtze and Huai rivers, comprise extensive low-lying plains and dense river networks. Understanding changes in these river network patterns is crucial for managing the hydrological cycle and ecological conservation in downstream areas. Our findings reveal a decline in river density (RD) from 1985 to 2016, while network connectivity (NC), network degree (D), and betweenness centrality (BC) have all increased, with BC showing the most significant rise, at 36.8%. At the single-factor scale, the geographical detector (GD) model identified human activity intensity (HAI) as the primary driving force for changes in the river pattern, which characterizes land use change. At the interaction scale, the joint effect of two factors generally exhibits non-linear enhancement, with the interaction between HAI and annual mean temperature significantly explaining the variations in RD and BC. Meanwhile, the spatiotemporal changes in NC and D are influenced by the joint effects of population density, gross domestic product (GDP), and natural meteorological factors such as annual mean natural runoff. Finally, the multiscale geographically weighted regression (MGWR) model effectively captured the spatial heterogeneity in the river network pattern's response to both natural and human activity drivers. The human activity factor, represented by GDP, exhibited a relatively wider range of scaled coefficients, indicating that the impact of human activities on river network pattern varies considerably across regions. This research advances our understanding of river network evolution and provides a scientific foundation for water resource management and ecological conservation in low-lying plain regions.