Your search keyword '"Ma, Xiaolin"' showing total 2 results

1. Changes of deep Pacific overturning circulation and carbonate chemistry during middle Miocene East Antarctic ice sheet expansion.

Author

Ma, Xiaolin, Tian, Jun, Ma, Wentao, Li, Ke, and Yu, Jimin

Subjects

*ATMOSPHERIC circulation, *MIOCENE Epoch, *CARBONATES, *ICE sheets, *CARBON cycle, ENVIRONMENTAL aspects

Abstract

East Antarctic ice sheet expansion (EAIE) at ∼13.9 Ma in the middle Miocene represents a major climatic event during the long-term Cenozoic cooling, but ocean circulation and carbon cycle changes during this event remain unclear. Here, we present new fish teeth isotope ( ε Nd) and benthic foraminiferal B/Ca records from the South China Sea (SCS), newly integrated meridional Pacific benthic foraminiferal δ 18 O and δ 13 C records and simulated results from a biogeochemical box model to explore the responses of deep Pacific Ocean circulation and carbon cycle across EAIE. The ε Nd and meridional benthic δ 13 C records reveal a more isolated Pacific Deep Water (PDW) and a sluggish Pacific meridional overturning circulation during the post-EAIE with respect to the pre-EAIE owing to weakened southern-sourced deep water formation. The deep-water [CO 2 − 3 ] and calcium carbonate mass accumulation rate in the SCS display markedly similar increases followed by recoveries to the pre-EAIE level during EAIE, which were probably caused by a shelf–basin shift of CaCO 3 deposition and strengthened weathering due to a sea level fall within EAIE. The model results show that the ∼1‰ positive δ 13 C excursion during EAIE could be attributed to increased weathering of high- δ 13 C shelf carbonates and a terrestrial carbon reservoir expansion. The drawdown of atmospheric CO 2 over the middle Miocene were probably caused by combined effects of increased shelf carbonate weathering, expanded land biosphere carbon storage and a sluggish deep Pacific meridional overturning circulation. [ABSTRACT FROM AUTHOR]

Published

2018

2. Ice sheet and terrestrial input impacts on the 100-kyr ocean carbon cycle during the Middle Miocene.

Author

Ma, Xiaolin, Ma, Wentao, Tian, Jun, Yu, Jimin, and Huang, Enqing

Subjects

*CARBON cycle, *ICE sheets, *MIOCENE Epoch, *ATMOSPHERIC carbon dioxide, *ANTARCTIC ice, *PRECIPITATION variability, *SUBGLACIAL lakes

Abstract

The Middle Miocene (~16–11.6 Ma) had atmospheric CO 2 levels comparable to the present day, and thus the mechanisms controlling the interactions of the climate system and the carbon cycle during the Middle Miocene may have significant implications for future climate change. In this study, we examined the phase relationship between benthic foraminiferal δ18O and δ13C records, within the 100-kyr band, during the Late Quaternary and the Middle Miocene. Our results suggest that benthic foraminiferal δ18O and δ13C were highly coherent and in-phase within the 100-kyr band during the Middle Miocene, in contrast to the anti-phased relationship during the Late Quaternary. However, the causes of this contrast remain elusive. We used a biogeochemical box model to explore the mechanisms of the in-phase relationship in the 100-kyr band during the Middle Miocene. The model results show that the in-phase relationship can be attributed to two mechanisms: (1) a shelf-basin carbonate shift regulated by sea-level fluctuations which originated from the growth and decay of the Antarctic ice sheet, within the 100-kyr band; and (2) changes in terrestrial carbon inputs and the biological pump driven by the discharge of riverine nutrients, which was regulated by precipitation variability in low latitudes, within the eccentricity-modulated precessional band. Thus, we propose that both high- and low-latitude processes played critical roles in the Middle Miocene carbon cycle, within the 100-kyr band. We further show that chemical weathering played a potential role in regulating the atmospheric p CO 2 on the orbital time scale during the Middle Miocene. • Phase relationships between benthic δ18O and δ13C records in the 100-kyr band are reinvestigated. • Terrestrial inputs explain the in-phase relationship of benthic δ18O and δ13C in the 100-kyr band over the Middle Miocene. • Both changes of Antarctic ice sheet and low-latitude precipitation played critical roles in the Middle Miocene carbon cycle. [ABSTRACT FROM AUTHOR]

Published

2022