A quantitative method of resolving annual precipitation for the past millennia from Tibetan ice cores

Net accumulation records derived from alpine ice cores provide the most direct measurement of past precipitation. However, quantitative reconstruction of accumulation for past millennia remains challenging due to the difficulty in identifying annual layers in the deeper sections of ice cores. In thi...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: W. Zhang, S. Hou, S.-Y. Wu, H. Pang, S. B. Sneed, E. V. Korotkikh, P. A. Mayewski, T. M. Jenk, M. Schwikowski
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2022
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Online Access:https://doi.org/10.5194/tc-16-1997-2022
https://doaj.org/article/d2fc16dd6c8244338efffca9f837e3ab
Description
Summary:Net accumulation records derived from alpine ice cores provide the most direct measurement of past precipitation. However, quantitative reconstruction of accumulation for past millennia remains challenging due to the difficulty in identifying annual layers in the deeper sections of ice cores. In this study, we propose a quantitative method to reconstruct annual accumulation from alpine ice cores for past millennia, using as an example an ice core drilled at the Chongce ice cap in the northwestern Tibetan Plateau (TP). First, we used laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) technology to develop ultra-high-resolution trace element records in three sections of the ice core and identified annual layers in each section based on seasonality of these elements. Second, based on nine 14 C ages determined for this ice core, we applied a two-parameter flow model to established the thinning parameter of this ice core. Finally, we converted the thickness of annual layers in the three sample sections to past accumulation rates based on the thinning parameter derived from the ice flow model. Our results show that the mean annual accumulation rates for the three sample sections are 109 mm yr −1 (2511–2541 years BP), 74 mm yr −1 (1682–1697 years BP), and 68 mm yr −1 (781–789 years BP), respectively. For comparison, the Holocene mean precipitation is 103 mm yr −1 . This method has the potential to reconstruct continuous high-resolution precipitation records covering millennia or even longer time periods.