Organic matter burial and degradation in the southern South China Sea since the last glaciation

IF 4 1区地球科学 Q1 GEOGRAPHY, PHYSICAL

Global and Planetary Change Pub Date : 2025-02-22 DOI:10.1016/j.gloplacha.2025.104771

Fen Chen , Shengyi Mao , Wanqiu Zhou , Gang Li , Xiaowei Zhu , Wen Yan

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引用次数: 0

Abstract

Marine organic matter (OM) plays a crucial role in regulating global carbon cycling and climate change; however, its significance is often underestimated or even overlooked due to the relatively low proportion of organic carbon (OC) within marine carbon pool and the insufficient documentation of coupled relationships between marine OM processes and atmospheric CO₂ changes during major climatic events, periods and cycles. Here, we present a high-resolution record of bulk parameters, organic biomarkers and inorganic elements to explore the potential one-to-one connection between marine OM source-to-sink dynamics and atmospheric CO₂ variations over the last glacial periods. Our results reveal that sedimentary OM was mainly of marine origin throughout the last glaciation, albeit the increases in terrestrial-derived OM inputs during the low-sea-level Last Glacial Maximum (LGM) and the sea-level rapid-rise deglacial meltwater pulse events. In the LGM, the lower-oxygen (intermediate and deep) waters and higher sedimentation rates facilitated the deposition and preservation of OM in waters and sediments, hence leading to higher TOC contents and contributing to lower atmospheric CO₂ concentrations. On the contrary, during the deglaciation and Holocene, the higher-oxygen intermediate waters and lower sedimentation rates promoted the remineralization of OM in the upper water column, which correlated with the rise in atmospheric CO₂ levels. However, the oxygen-depleted intermediate waters and highest sedimentation rates in the Bølling-Allerød (B/A) time greatly accelerated the downward transportation of OM with insignificant degradation in upper waters. The sinking OM experienced further remineralization at water-sediment interface, as indicated by a marked negative excursion in bottom-water oxygenation. This process exemplifies the biological pump, thereby acting to slow down atmospheric CO₂ rise during the B/A warm interval. Our study presents a potential mechanism to interpret atmospheric CO₂ variability by invoking marine OM dynamics, with particular emphasis on the place where OM degradation takes.

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末次冰期以来南海南部有机质埋藏与降解

海洋有机质在调节全球碳循环和气候变化中起着至关重要的作用；然而，由于海洋碳库中有机碳（OC）的比例相对较低，以及在重大气候事件、时期和周期中海洋有机质过程与大气CO2变化之间的耦合关系文献不足，其重要性往往被低估甚至忽视。在这里，我们提供了体积参数、有机生物标志物和无机元素的高分辨率记录，以探索末次冰期海洋OM源-汇动力学与大气CO2变化之间潜在的一对一联系。研究结果表明，末次冰期沉积有机质主要来自海洋，但在低海平面末次盛冰期（LGM）和海平面快速上升的冰川融水脉冲事件期间，陆源有机质输入有所增加。在LGM中，低氧（中深层）水体和较高的沉积速率促进了OM在水体和沉积物中的沉积和保存，从而导致TOC含量升高，并导致大气CO2浓度降低。相反，在去冰期和全新世，高氧中间水和低沉积速率促进了上层水柱OM的再矿化，这与大气CO2水平的升高有关。而在Bølling- allero ød （B/A）时段，缺氧的中间水域和最高的沉积速率极大地加速了OM的下移，而上层水域的退化程度不明显。下沉的有机质在水-沉积物界面经历了进一步的再矿化，表现为明显的底水氧化负偏移。这一过程体现了生物泵的作用，从而减缓了B/A暖间隔期间大气中二氧化碳的上升。我们的研究提出了一种潜在的机制，通过援引海洋有机质动力学来解释大气CO2的变化，特别强调了有机质降解发生的地方。

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来源期刊

Global and Planetary Change 地学天文-地球科学综合

CiteScore

7.40

自引率

10.30%

发文量

226

审稿时长

63 days

期刊介绍： The objective of the journal Global and Planetary Change is to provide a multi-disciplinary overview of the processes taking place in the Earth System and involved in planetary change over time. The journal focuses on records of the past and current state of the earth system, and future scenarios , and their link to global environmental change. Regional or process-oriented studies are welcome if they discuss global implications. Topics include, but are not limited to, changes in the dynamics and composition of the atmosphere, oceans and cryosphere, as well as climate change, sea level variation, observations/modelling of Earth processes from deep to (near-)surface and their coupling, global ecology, biogeography and the resilience/thresholds in ecosystems. Key criteria for the consideration of manuscripts are (a) the relevance for the global scientific community and/or (b) the wider implications for global scale problems, preferably combined with (c) having a significance beyond a single discipline. A clear focus on key processes associated with planetary scale change is strongly encouraged. Manuscripts can be submitted as either research contributions or as a review article. Every effort should be made towards the presentation of research outcomes in an understandable way for a broad readership.