Changes in chemical weathering regime of shelf sediments of the East China Sea controlled by sea-level and climatic changes since the last deglaciation.

[Display omitted] • Al/Si ratios can be used to correct CIA values to avoid the influence of grain-size sorting. • CIA values decreased during the YD, 8.2 ka, and 4.2 ka cold events during the Holocene. • Chemical weathering could be enhanced due to shelf exposure when the sea level is low. • Chemical weathering shelf sediments could rapidly respond to abrupt climate events. Chemical weathering of shelf sediments is important in driving the global elemental cycle and climate to maintain the earth's habitability. However, the response mechanism between chemical weathering of shelf sediments and climate and sea-level changes is still unclear. This study focuses on core ECMZ located in the mud area of the East China Sea (ECS) inner shelf. The results indicate that the mechanisms controlling chemical weathering in the sediment of the ECS inner shelf differ at different timescales. On the orbital time scale, the Chemical Index of Alteration (CIA) indicates that the intensity of chemical weathering in sediments during the deglacial period was significantly higher than that during the Holocene. This was caused by shelf exposure during low sea-level periods when the sediments were fully exposed and the residence time in the weathering zone was long, leading the shelf sediments to undergo consistent and complete weathering under supply-limited conditions. In comparison, during cold events on the millennium-centennial time scale, such as Younger Dryas, 8.2 ka, and 4.2 ka, chemical weathering was weaker (lower CIA values) due to accelerated erosion as a result of lower temperatures and higher precipitation, which shortened the rocks' residence in the weathering zone, resulting in the control of chemical weathering shifted from supply factors to kinetic ones, such as temperature and precipitation. Our findings suggest that on the orbital time scale, glacial shelf exposure could enhance chemical weathering, thereby reducing atmospheric CO 2 ; on the millennium-centennial time scale, chemical weathering could rapidly respond to abrupt climate events. [ABSTRACT FROM AUTHOR]