Quantitative reconstruction of Holocene sediment source variations in the Yellow and northern East China Seas and their forcings.

Sediment provenance in the Yellow Sea and northern East China Seas (YECSs) has long been a subject of interest, but its quantification is still inconclusive. Here, we present an improved Al Mg regression analysis by refining its methodological approach to strengthen quantification of sediment source-to-sink transports in the YECSs, with focus on its forcing mechanisms during the Holocene. Our quantitative source estimates clearly depict a considerable supply of the Chinese river (CR) sediments (~50%) to the southwestern Korean coastal region, and the Korean river (KR) sediments (30–40%) to the Central Yellow Sea Mud deposit, which accounts for a good balance between the sediment supply and budget of the shelf deposit. Of particular note is an abrupt decline in the CR contributions around 124°E, which indicates that the CR sediments do not directly reach the eastern part of the Yellow Sea blocked by a strong physical boundary. Further, the observed variations in proportions between Huanghe-, Changjiang- and Korean river-derived sediments over the last 15 kyr – notably an abrupt increase of CR contribution since ~7 ka, followed by a sudden drop at ~3–4 ka – exhibit a good correspondence with other mineralogical proxy records. These temporal provenance changes witnessed robust palaeoenvironmental signals which fit to major climatic and oceanographic events linked with sea-level, intensity of the Kuroshio Current inflow and the East Asian monsoon. This study improves understanding of what pathways and sinks exist within the YECS basin, and how rates of sediment supply from adjacent rivers have changed over time. • An improved Al Mg regression analysis for quantifying sediment source in the YECSs is proposed. • Our estimation well defines spatiotemporal sediment source-to-sink dynamics in the sea. • Sedimentary deposits are characterized by different proportions of the sources over the last 15 kyr • This study provides a broader understanding of the present- and paleo-depositional systems of the sea. [ABSTRACT FROM AUTHOR]