Review
Ferromanganese oxide deposits: Geochemical and microbiological perspectives of interactions of cobalt and nickel

https://doi.org/10.1016/j.oregeorev.2021.104458Get rights and content
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Highlights

  • Surveys the diversity and differences in microbial community composition of Fe-Mn mineral deposits.

  • Addresses the interactions of cobalt and nickel on ferromanganese (Fe-Mn) mineral deposits.

  • List the different advanced methods to study and differentiate between biological and abiological components of manganese crusts.

  • Serves as a suitable reference to deduce the role of microbes in governing mineral precipitation and growth.

Abstract

Bacterial participation in the formation of ferromanganese (Fe-Mn) mineral deposits is highly debated, as the precipitation of metals could occur by both chemical and biologically mediated mechanisms. Besides, the enrichment of trace metals like Co and Ni in Fe-Mn deposits is further complicated by the aging process of the crust, scavenging by the Fe-Mn oxide surfaces and co-precipitation by bacterial activity. The concentration of Co in Fe-Mn crusts varies from 0.1 to 1.9% and Ni from 0.2 to 1.1% in individual bulk crusts implying marked heterogeneity in their composition. Several reviews address different aspects like the molecular mechanisms of Co and Ni uptake in bacteria, enzymes containing Ni and Co and their relative toxicity. Nonetheless, only limited data are available on the interactions of Co and Ni with bacteria and how they contribute to the enrichment of these metals in the deep-sea mineral deposits. Hence, this review focuses on the geochemical and microbiological perspective of the interactions of Co and Ni, different modes of their enrichment and requirement for several physiological and biogeochemical processes in bacteria. The detailed survey of the studies indicates that both chemical and biological mechanisms promote the accretion and dissolution of minerals with bacteria accelerating the net oxidation–reduction reactions in their directions. Combined geochemical and microbiological interactions in conjunction with detailed molecular analysis would further confine processes affecting Fe-Mn mineral formation.

Keywords

Extracellular
Intracellular
Cell-surface
Hydrogenetic
Diagenetic
Hydrothermal

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