Seasonal cycles of biogeochemical fluxes in the Scotia Sea, Southern Ocean: a stable isotope approach

IF 3.9 2区 地球科学 Q1 ECOLOGY Biogeosciences Pub Date : 2023-08-25 DOI:10.5194/bg-20-3573-2023
A. Belcher, S. Henley, K. Hendry, M. Wootton, L. Friberg, Ursula Dallman, Tongli Wang, C. Coath, C. Manno
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Abstract

Abstract. The biological carbon pump is responsible for much of the decadal variability in the ocean carbon dioxide (CO2) sink, driving the transfer of carbon from the atmosphere to the deep ocean. A mechanistic understanding of the ecological drivers of particulate organic carbon (POC) flux is key both to the assessment of the magnitude of the ocean CO2 sink and for accurate predictions as to how this will change with changing climate. This is particularly important in the Southern Ocean, a key region for the uptake of CO2 and the supply of nutrients to the global thermocline. In this study we examine sediment-trap-derived particle fluxes and stable isotope signatures of carbon (C), nitrogen (N), and biogenic silica (BSi) at a study site in the biologically productive waters of the northern Scotia Sea in the Southern Ocean. Both deep (2000 m) and shallow (400 m) sediment traps exhibited two main peaks in POC, particulate N, and BSi flux: one in austral spring and one in summer, reflecting periods of high surface productivity. Particulate fluxes and isotopic compositions were similar in both deep and shallow sediment traps, highlighting that most remineralisation occurred in the upper 400 m of the water column. Differences in the seasonal cycles of isotopic compositions of C, N, and Si provide insights into the degree of coupling of these key nutrients. We measured increasing isotopic enrichment of POC and BSi in spring, consistent with fractionation during biological uptake. Since we observed isotopically light particulate material in the traps in summer, we suggest physically mediated replenishment of lighter isotopes of key nutrients from depth, enabling the full expression of the isotopic fractionation associated with biological uptake. The change in the nutrient and remineralisation regimes, indicated by the different isotopic compositions of the spring and summer productive periods, suggests a change in the source region of material reaching the traps and associated shifts in phytoplankton community structure. This, combined with the occurrence of advective inputs at certain times of the year, highlights the need to make synchronous measurements of physical processes to improve our ability to track changes in the source regions of sinking particulate material. We also highlight the need to conduct particle-specific (e.g. faecal pellets, phytoplankton detritus, zooplankton moults) isotopic analysis to improve the use of this tool in assessing particle composition of the sinking material and to develop our understanding of the drivers of biogeochemical fluxes.
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南大洋斯科舍海生物地球化学通量的季节循环:一种稳定同位素方法
摘要生物碳泵负责海洋二氧化碳(CO2)汇的大部分十年变化,推动碳从大气转移到深海。了解颗粒有机碳(POC)通量的生态驱动因素是评估海洋CO2链规模和准确预测其将如何随着气候变化而变化的关键。这在南大洋尤为重要,南大洋是吸收二氧化碳和向全球温跃层供应营养物质的关键区域。在这项研究中,我们在南大洋斯科舍海北部生物生产水域的一个研究地点检查了沉积物陷阱衍生的颗粒通量和碳(C)、氮(N)和生物二氧化硅(BSi)的稳定同位素特征。两者都很深(2000 m) andshallow(400 m) 沉积物陷阱在POC、颗粒氮和BSi通量上表现出两个主峰:一个在南春,一个在夏季,反映了地表生产力高的时期。深部和浅部沉积物圈闭中的颗粒通量和同位素组成相似,这突出表明大多数沉积物矿化发生在上部400 m水柱。C、N和Siprovide同位素组成季节周期的差异深入了解了这些关键营养素的耦合程度。我们测量了POC和BSi在春季的同位素富集增加,与生物吸收过程中的分馏一致。由于我们在夏季的捕集器中观察到同位素烯丙基轻颗粒物质,我们建议通过物理介导的方式从深处补充关键营养物质的轻同位素,使与生物吸收相关的同位素分馏能够充分表达。春季和夏季生产期不同的同位素组成表明,营养和再矿化机制的变化表明,到达陷阱的物质来源区域发生了变化,浮游植物群落结构也发生了相应的变化。这一点,再加上一年中某些时候平流输入的出现,突出了对物理过程进行同步测量的必要性,以提高我们跟踪下沉颗粒物质来源区域变化的能力。我们还强调了进行颗粒特异性(如粪便颗粒、浮游植物碎屑、浮游动物蜕皮)同位素分析的必要性,以改进该工具的使用,从而分析下沉物质的颗粒组成,并加深我们对生物地球化学通量驱动因素的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biogeosciences
Biogeosciences 环境科学-地球科学综合
CiteScore
8.60
自引率
8.20%
发文量
258
审稿时长
4.2 months
期刊介绍: Biogeosciences (BG) is an international scientific journal dedicated to the publication and discussion of research articles, short communications and review papers on all aspects of the interactions between the biological, chemical and physical processes in terrestrial or extraterrestrial life with the geosphere, hydrosphere and atmosphere. The objective of the journal is to cut across the boundaries of established sciences and achieve an interdisciplinary view of these interactions. Experimental, conceptual and modelling approaches are welcome.
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