L. Ghazi, K. E. Grant, A. Chappaz, M. Danish, B. Peucker-Ehrenbrink, J. C. Pett-Ridge
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引用次数: 0
摘要
本文首次全面综述了目前已知的地球表面铼(Re)的不同自然通量和人为通量。我们强调了人为活动对铼的重要作用,这是在生物地球化学示踪剂或替代物的背景下利用铼的一个重要考虑因素。Re 的最大自然通量来自化学风化和向海洋的河流迁移(溶解 = 62 × 106 g yr-1 和颗粒 = 5 × 106 g yr-1)。本综述报告了新的全球平均[Re]值,即 16 ± 2 pmol L-1,或 10 ± 1 pmol L-1(推断在没有人类活动影响的情况下,流入海洋的河流的前人类活动浓度)。人类活动通过采矿(包括二次移动)、燃煤和石油燃烧移动了大约 560 × 106 g yr-1 的 Re,这比任何自然的 Re 通量都要多。值得进一步研究的 Re 通量包括:海底地下水排放、降水(陆地和海洋)、岩浆脱气和热液活动。对这些通量的释放(源)或封存(汇)机制和主要主相仍知之甚少。这项研究还强调了利用溶解的[Re]浓度作为岩石有机碳氧化的示踪剂,以及利用稳定的Re同位素作为全球氧化还原条件变化的代用指标。
This paper is the first comprehensive synthesis of what is currently known about the different natural and anthropogenic fluxes of rhenium (Re) on Earth's surface. We highlight the significant role of anthropogenic mobilization of Re, which is an important consideration in utilizing Re in the context of a biogeochemical tracer or proxy. The largest natural flux of Re derives from chemical weathering and riverine transport to the ocean (dissolved = 62 × 106 g yr−1 and particulate = 5 × 106 g yr−1). This review reports a new global average [Re] of 16 ± 2 pmol L−1, or 10 ± 1 pmol L−1 for the inferred pre-anthropogenic concentration without human impact, for rivers draining to the ocean. Human activity via mining (including secondary mobilization), coal combustion, and petroleum combustion mobilize approximately 560 × 106 g yr−1 Re, which is more than any natural flux of Re. There are several poorly constrained fluxes of Re that merit further research, including: submarine groundwater discharge, precipitation (terrestrial and oceanic), magma degassing, and hydrothermal activity. The mechanisms and the main host phases responsible for releasing (sources) or sequestrating (sinks) these fluxes remain poorly understood. This study also highlights the use of dissolved [Re] concentrations as a tracer of oxidation of petrogenic organic carbon, and stable Re isotopes as proxies for changes in global redox conditions.
期刊介绍:
Global Biogeochemical Cycles (GBC) features research on regional to global biogeochemical interactions, as well as more local studies that demonstrate fundamental implications for biogeochemical processing at regional or global scales. Published papers draw on a wide array of methods and knowledge and extend in time from the deep geologic past to recent historical and potential future interactions. This broad scope includes studies that elucidate human activities as interactive components of biogeochemical cycles and physical Earth Systems including climate. Authors are required to make their work accessible to a broad interdisciplinary range of scientists.
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