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Isotopic Fingerprints of Paleoclimates during the Last 30,000 Years in Deep Confined Groundwaters of Southern India

Published online by Cambridge University Press:  20 January 2017

Balbir Singh Sukhija
Affiliation:
National Geophysical Research Institute, Hyderabad, -500 007, India
Dontireddy Venkat Reddy
Affiliation:
National Geophysical Research Institute, Hyderabad, -500 007, India
Pasupuleti Nagabhushanam
Affiliation:
National Geophysical Research Institute, Hyderabad, -500 007, India

Abstract

Isotopic and geochemical evidence of paleoclimates, especially for the last glaciation, has been obtained from deep confined groundwaters of southern India. The δ13C, δ18O, chloride, and deuterium analyses of groundwaters show distinct excursions inferred to be related to climatic variations. The arid climatic episode associated with the last glaciation (18,000 ± 2000 yr B.P.) is conspicuously identified by signatures of relatively enriched δ13C (−10 to −12‰ PDB) and δ18O (−5.3 to −4.8‰ SMOW) values, and high chloride concentration (80 to 160 mg/l). The transition from an arid to humid period ca. 12,000–8000 yr B.P. is shown by a decreasing trend in the δ13C (−9.5 to −17‰) and δ18O (−4.5 to −6.3‰) contents of groundwaters. The late Holocene (since 4000 yr B.P.), marked by a more humid but unstable climate, is identified by further depletion of δ13C (−13 to −20‰) and δ18O (−5.2 to −6.3‰). Similar variation between δ18O and chloride values in confined groundwaters further demonstrates two distinct climatic excursions (arid and humid) governed by the “amount effect.” This is the first time that isotopic and geochemical signatures related to changing paleoclimates have been identified in the confined groundwaters of the southern Indian landmass.

Type
Original Articles
Copyright
University of Washington

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