Changes in Indian Summer Monsoon Using Neodymium (Nd) Isotopes in the Andaman Sea During the Last 24,000 years

Dramatic changes from a cold and dry last glacial to a warm and wet Holocene period intensified the Indian summer monsoon (ISM), resulting in vigorous hydrology and increased terrestrial erosion. Here we present seawater neodymium (Nd) data (expressed in epsilon (Nd)) from Andaman Sea sediments to assess past changes in the ISM and the related impact of Irrawaddy-Salween and Sittoung (ISS) river discharge into the Andaman Sea in the northeastern Indian Ocean. Four major isotopic changes were identified: (1) a gradual increase in epsilon (Nd) toward a more radiogenic signature during the Last Glacial Maximum (22-18 ka), suggesting a gradual decrease in the ISS discharge; (2) a relatively stable radiogenic seawater epsilon (Nd) between 17.2 and 8.8 ka, perhaps related to a stable reduced outflow; (3) a rapid transition to less radiogenic epsilon (Nd) signature after 8.8 ka, reflecting a very wet early-mid-Holocene with the highest discharge; and (4) a decrease in epsilon (Nd) signal stability in the mid-late Holocene. Taking into account the contribution of the ISS rivers to the Andaman Sea epsilon (Nd) signature that changes proportionally with the strengthening (less radiogenic epsilon (Nd)) or weakening (more radiogenic epsilon (Nd)) of the ISM, we propose a binary model mixing between the Salween and Irrawaddy rivers to explain the epsilon (Nd) variability in Andaman Sea sediments. We hypothesize that the Irrawaddy river mainly contributed detrital sediment to the northeastern Andaman Sea for the past 24 ka. Our epsilon (Nd) data shed new light on the regional changes in Indo-Asian monsoon systems when compared with the existing Indian and Chinese paleo-proxy records.