Modern oceanic cycle of beryllium isotopes assessed using a data-constrained biogeochemical model

IF 4.5 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Kai Deng, Gregory F. de Souza, Jianghui Du
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引用次数: 0

Abstract

Beryllium isotopes (stable 9Be and cosmogenic meteoric 10Be) enter the oceans through distinct pathways – i.e., from the continents and the atmosphere respectively – and display non-conservative behaviour in seawater. This isotope system has served as a powerful tool for quantifying a variety of processes, including geomagnetism, sedimentation, continental input, and ocean circulation. However, processes at land–ocean boundaries and within the ocean interior may either amplify or buffer the seawater isotope response to environmental changes. In the last decade, substantial effort has been invested in understanding external sources and internal cycling of Be isotopes, offering an excellent opportunity to revisit their modern oceanic cycle. Here, we investigate the controls on the modern oceanic cycling of Be isotopes using a three-dimensional ocean model, constrained by observational data on input fluxes and water-column distributions of 9Be and 10Be. In addition to modelling the previously known controls, we highlight the key role of marine benthic fluxes and scavenging onto particulate organic matter and opal in determining the mass balance and spatial distribution of Be isotopes. Inter-basin Be transport by the circulation is less important than external inputs at continent/atmosphere–ocean boundaries, except in the South Pacific. Therefore, the distribution of seawater 10Be/9Be ratios largely reflects that of the external inputs in most basins in the modern ocean. Finally, we apply our data-constrained mechanistic model to test the sensitivity of basin-wide 10Be/9Be ratios to changes of external sources and internal cycling. This analysis shows that seawater 10Be/9Be ratios are to some extent buffered against changes in continental denudation. For example, a 50 % decrease in denudation rates results in a 13–48 % increase in ocean-wide 10Be/9Be ratios. Moreover, the interplay between particle scavenging and ocean circulation can cause divergent responses in 10Be/9Be ratios in different basins. Weaker scavenging (e.g., 50 % decrease in intensity) would increase the homogenising effect of ocean circulation, making North Atlantic and North Pacific 10Be/9Be ratios converge (∼20 % change in isotope ratios). The mechanistic understanding developed from this Be cycling model provides important insights into the various applications of marine Be isotopes, and offers additional tools to assess the causes of spatio-temporal Be isotope variations. We also identify the key oceanic processes that require further constraints to achieve a complete understanding of Be cycling in the modern ocean and back through time.
利用数据约束生物地球化学模型评估铍同位素的现代海洋循环
铍同位素(稳定铍 9Be 和宇宙陨变铍 10Be)通过不同的途径进入海洋,即分别从大陆和大气中进入,并在海水中表现出非保守行为。这一同位素系统是量化地磁、沉积、大陆输入和海洋环流等各种过程的有力工具。然而,陆地-海洋边界和海洋内部的过程可能会放大或缓冲海水同位素对环境变化的反应。在过去十年中,人们投入了大量精力来了解 Be 同位素的外部来源和内部循环,这为重新审视其现代海洋循环提供了绝佳机会。在此,我们利用一个三维海洋模型,在 9Be 和 10Be 输入通量和水柱分布观测数据的约束下,研究了 Be 同位素现代海洋循环的控制因素。除了模拟以前已知的控制因素外,我们还强调了海洋底栖通量以及颗粒有机物和蛋白石的清扫在决定 Be 同位素的质量平衡和空间分布方面的关键作用。除南太平洋外,在大陆/大气-海洋边界,环流造成的盆地间 Be 迁移不如外部输入重要。因此,海水 10Be/9Be 比率的分布在很大程度上反映了现代海洋中大多数盆地的外部输入。最后,我们应用数据约束机理模型检验了全海盆 10Be/9Be 比率对外部来源和内部循环变化的敏感性。分析表明,海水 10Be/9Be 比率在一定程度上可以缓冲大陆剥蚀的变化。例如,剥蚀率降低 50%,整个海洋的 10Be/9Be 比率就会增加 13-48%。此外,粒子清除和大洋环流之间的相互作用会导致不同海盆中 10Be/9Be 比率的不同反应。较弱的粒子清除(例如强度下降 50%)会增加海洋环流的同质化效应,使北大西洋和北太平洋的 10Be/9Be 比率趋同(同位素比率变化 ∼ 20%)。从这一 Be 循环模型中获得的机理认识为海洋 Be 同位素的各种应用提供了重要启示,并为评估 Be 同位素时空变化的原因提供了更多工具。我们还确定了需要进一步制约的关键海洋过程,以便全面了解 Be 在现代海洋中的循环情况和时间回溯。
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
Geochimica et Cosmochimica Acta
Geochimica et Cosmochimica Acta 地学-地球化学与地球物理
CiteScore
9.60
自引率
14.00%
发文量
437
审稿时长
6 months
期刊介绍: Geochimica et Cosmochimica Acta publishes research papers in a wide range of subjects in terrestrial geochemistry, meteoritics, and planetary geochemistry. The scope of the journal includes: 1). Physical chemistry of gases, aqueous solutions, glasses, and crystalline solids 2). Igneous and metamorphic petrology 3). Chemical processes in the atmosphere, hydrosphere, biosphere, and lithosphere of the Earth 4). Organic geochemistry 5). Isotope geochemistry 6). Meteoritics and meteorite impacts 7). Lunar science; and 8). Planetary geochemistry.
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