Molybdenum Mobility During Managed Aquifer Recharge in Carbonate Aquifers

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Abstract

The mobility of molybdenum (Mo) in groundwater systems has received little attention, although a high intake of Mo is known to be detrimental to human and animal health. Here, we used a comprehensive hydrochemical data set collected during a multi-cycle aquifer storage and recovery test to study the mechanisms that control the mobility of Mo under spatially and temporally varying hydrochemical conditions. The model-based interpretation of the data indicated that the initial mobilization of Mo occurs as a sequence of reactions, in which (i) the aerobic injectant induces pyrite oxidation, (ii) the released acidity is partially buffered by the dissolution of dolomite that (iii) leads to the release of Mo with highly soluble sulfurized organic matter prevailing between the intercrystalline spaces of the dolomite matrix or incorporated in dolomite crystals. Once released, Mo mobility was primarily controlled by pH-dependent surface complexation reactions to the sediments and, to a lesser extent, the capture by iron sulfides (FeS). In the studied system, Mo mobilization could be effectively mitigated by reducing or eliminating pyrite oxidation, which decreases the likelihood of dolomite dissolution and associated Mo release.

Abstract

This study identifies and quantifies the processes controlling the mobility of Mo in a carbonate aquifer.

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A whiff of oxygen before the great oxidation event?

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High-resolution chemostratigraphy reveals an episode of enrichment of the redox-sensitive transition metals molybdenum and rhenium in the late Archean Mount McRae Shale in Western Australia. Correlations with organic carbon indicate that these metals were derived from contemporaneous seawater. Rhenium/osmium geochronology demonstrates that the enrichment is a primary sedimentary feature dating to 2501 +/- 8 million years ago (Ma). Molybdenum and rhenium were probably supplied to Archean oceans by oxidative weathering of crustal sulfide minerals. These findings point to the presence of small amounts of O2 in the environment more than 50 million years before the start of the Great Oxidation Event.

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Author and article information

Journal

Journal ID (nlm-ta): Environ Sci Technol

Journal ID (iso-abbrev): Environ Sci Technol

Journal ID (publisher-id): es

Journal ID (coden): esthag

Title: Environmental Science & Technology

Publisher: American Chemical Society

ISSN (Print): 0013-936X

ISSN (Electronic): 1520-5851

Publication date (Electronic): 01 May 2023

Publication date Collection: 16 May 2023

Volume: 57

Issue: 19

Pages: 7478-7489

Affiliations

[† ]Institute of Geosciences, University of Bremen , Klagenfurter Str. 2-4, 28359 Bremen, Germany

[‡ ]CSIRO Land and Water , Private Bag No. 5, Wembley 6913, Western Australia, Australia

[§ ]School of Earth Sciences, University of Western Australia , 35 Stirling Hwy, Perth 6009, Western Australia, Australia

Author notes

[* ]Email: henning.prommer@ 123456csiro.au .

Author information

Sarah Koopmann https://orcid.org/0000-0001-6809-7994

Henning Prommer https://orcid.org/0000-0002-8669-8184

Adam Siade https://orcid.org/0000-0003-3840-5874

Thomas Pichler https://orcid.org/0000-0003-3327-2451

Article

DOI: 10.1021/acs.est.2c08619

PMC ID: 10193584

PubMed ID: 37126233

SO-VID: ac432153-b9f0-48e6-8f51-c639d56278e8

License:

Permits non-commercial access and re-use, provided that author attribution and integrity are maintained; but does not permit creation of adaptations or other derivative works ( https://creativecommons.org/licenses/by-nc-nd/4.0/).