大量的孔隙水 Mn(III) 是沉积氧化还原系统的主要组成部分。

Abundant porewater Mn(III) is a major component of the sedimentary redox system.

机构信息

School of Marine Science and Policy, University of Delaware, Lewes, DE 19958, USA.

出版信息

Science. 2013 Aug 23;341(6148):875-8. doi: 10.1126/science.1241396.

Abstract

Soluble manganese(III) [Mn(III)] can potentially serve as both oxidant and reductant in one-electron-transfer reactions with other redox species. In near-surface sediment porewater, it is often overlooked as a major component of Mn cycling. Applying a spectrophotometric kinetic method to hemipelagic sediments from the Laurentian Trough (Quebec, Canada), we found that soluble Mn(III), likely stabilized by organic or inorganic ligands, accounts for up to 90% of the total dissolved Mn pool. Vertical profiles of dissolved oxygen and dissolved and solid Mn suggest that soluble Mn(III) is primarily produced via oxidation of Mn(II) diffusing upwards from anoxic sediments with lesser contributions from biotic and abiotic reductive dissolution of MnO2. The conceptual model of the sedimentary redox cycle should therefore explicitly include dissolved Mn(III).

摘要

可溶性三价锰 (Mn(III)) 在与其他氧化还原物种的单电子转移反应中可能同时充当氧化剂和还原剂。在近地表沉积物孔隙水中，它通常被忽视为锰循环的主要组成部分。应用分光光度动力学方法对来自劳伦太德槽（加拿大魁北克）的半深海沉积物进行研究，我们发现，可溶性 Mn(III) 可能被有机或无机配体稳定，占总溶解 Mn 库的高达 90%。溶解氧、溶解态和固态 Mn 的垂直分布表明，可溶性 Mn(III) 主要通过从缺氧沉积物向上扩散的 Mn(II) 的氧化产生，生物和非生物还原 MnO2 的贡献较小。因此，沉积态氧化还原循环的概念模型应明确包括可溶性 Mn(III)。

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大量的孔隙水 Mn(III) 是沉积氧化还原系统的主要组成部分。

Abundant porewater Mn(III) is a major component of the sedimentary redox system.

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