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解析海洋生物泵中碳通量衰减的驱动因素。

Decoding drivers of carbon flux attenuation in the oceanic biological pump.

机构信息

Sorbonne Université, CNRS, Laboratoire d'Océanographie de Villefranche, Villefranche-sur-Mer, France.

Institute for Marine and Antarctic Studies, University of Tasmania, Hobart, Tasmania, Australia.

出版信息

Nature. 2024 Sep;633(8030):587-593. doi: 10.1038/s41586-024-07850-x. Epub 2024 Sep 11.

DOI:10.1038/s41586-024-07850-x
PMID:39261723
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11410664/
Abstract

The biological pump supplies carbon to the oceans' interior, driving long-term carbon sequestration and providing energy for deep-sea ecosystems. Its efficiency is set by transformations of newly formed particles in the euphotic zone, followed by vertical flux attenuation via mesopelagic processes. Depth attenuation of the particulate organic carbon (POC) flux is modulated by multiple processes involving zooplankton and/or microbes. Nevertheless, it continues to be mainly parameterized using an empirically derived relationship, the 'Martin curve'. The derived power-law exponent is the standard metric used to compare flux attenuation patterns across oceanic provinces. Here we present in situ experimental findings from C-RESPIRE, a dual particle interceptor and incubator deployed at multiple mesopelagic depths, measuring microbially mediated POC flux attenuation. We find that across six contrasting oceanic regimes, representing a 30-fold range in POC flux, degradation by particle-attached microbes comprised 7-29 per cent of flux attenuation, implying a more influential role for zooplankton in flux attenuation. Microbial remineralization, normalized to POC flux, ranged by 20-fold across sites and depths, with the lowest rates at high POC fluxes. Vertical trends, of up to threefold changes, were linked to strong temperature gradients at low-latitude sites. In contrast, temperature played a lesser role at mid- and high-latitude sites, where vertical trends may be set jointly by particle biochemistry, fragmentation and microbial ecophysiology. This deconstruction of the Martin curve reveals the underpinning mechanisms that drive microbially mediated POC flux attenuation across oceanic provinces.

摘要

生物泵将碳输送到海洋内部,驱动长期碳封存,并为深海生态系统提供能量。它的效率由真光层中新形成颗粒的转化决定,然后通过中层过程垂直通量衰减。颗粒有机碳(POC)通量的深度衰减受到涉及浮游动物和/或微生物的多个过程的调节。然而,它仍然主要通过经验衍生关系“Martin 曲线”进行参数化。所得幂律指数是用于比较海洋省之间通量衰减模式的标准度量。在这里,我们展示了 C-RESPIRE 的现场实验结果,C-RESPIRE 是一个双颗粒拦截器和孵化器,部署在多个中层深度,测量微生物介导的 POC 通量衰减。我们发现,在六个具有代表性的海洋区域(跨越 30 倍的 POC 通量范围)中,颗粒附着微生物的降解占通量衰减的 7-29%,这意味着浮游动物在通量衰减中起着更重要的作用。微生物矿化作用与 POC 通量的归一化范围为 20 倍,在高 POC 通量处速率最低。垂直趋势变化高达三倍,与低纬度站点的强烈温度梯度有关。相比之下,温度在中纬度和高纬度站点的作用较小,那里的垂直趋势可能由颗粒生物化学、碎裂和微生物生理生态学共同决定。Martin 曲线的这种解构揭示了驱动海洋省之间微生物介导的 POC 通量衰减的基础机制。

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