Update papers.bib

mchevalier2 · Oct 5, 2023 · 87287bf · 87287bf
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@@ -133,6 +133,20 @@ @article{Chevalier_etal_2014
     html = {https://www.doi.org/10.5194/cp-10-2081-2014}
 }
 
+@article{HUI2023111808,
+title = {Middle Miocene evolution of East Asian summer monsoon precipitation in the northeast part of the Tibetan Plateau based on a quantitative analysis of palynological records},
+journal = {Palaeogeography, Palaeoclimatology, Palaeoecology},
+volume = {630},
+pages = {111808},
+year = {2023},
+issn = {0031-0182},
+doi = {https://doi.org/10.1016/j.palaeo.2023.111808},
+url = {https://www.sciencedirect.com/science/article/pii/S0031018223004261},
+author = {Zhengchuang Hui and Xiao Wei and Zhendong Xue and Xuerong Zhao and Manuel Chevalier and Xue Lu and Jun Zhang and Tingjiang Peng and Yingyong Chen and Peng Chen},
+keywords = {Sporopollen, Quantitative climate reconstructions, CREST, Middle Miocene, EASM precipitation, NE Tibetan Plateau},
+abstract = {Characterized by elevated pCO2 levels and global warmth, the mid-Miocene climate is a valuable analogue for investigating how the East Asian Summer Monsoon (EASM) may evolve at different time scales. In this paper, we present a quantitative EASM precipitation record with a temporal resolution of ∼14 kyr during the mid-Miocene (∼15.97 to 13.64 Ma) by applying the probabilistic CREST (Climate Reconstruction Software) method to palynological records from the northeast part of the Tibetan Plateau. Reconstructed mid-Miocene EASM precipitation (∼860 mm) was almost twice that of today (∼450 mm), indicating much stronger EASM intensity. The reconstruction shows a gradual long-term decline on which was superimposed a stronger EASM period (∼15.97–14.54 Ma) followed by a relatively stable period (∼14.54–13.84 Ma) and a short period of reduced precipitation (∼13.84–13.64 Ma). The correspondence of EASM precipitation changes with the mid-Miocene climate optimum and west-east thermal gradients in equatorial Pacific suggests these two factors were the main driving forces for EASM evolution from ∼15.97 to 14.54 Ma, whereas the combined impact of global cooling and the northward shift of the Intertropical Convergence Zone is probably responsible for the slight decline of the EASM from ∼14.54 to 13.84 Ma. The weaker EASM between ∼13.84 and 13.64 Ma was most likely a response to the global significant cooling event Mi-3. On orbital time scales, the precipitation records exhibit a dominant ∼400 kyr periodicity, indicating EASM changes were mainly paced by eccentricity via the modulation of precessional amplitude, and the East Antarctic Ice Sheet variations were probably another important driving force.}
+}
+
 @article{hui_multiple_2023,
 	title = {Multiple forcing on {Late} {Miocene} {East} {Asian} {Summer} {Monsoon} {Precipitation} {Variability} in {NE} {Tibetan} {Plateau}},
 	volume = {221},