The biogeochemistry of ferruginous lakes and past ferruginous oceans

Elizabeth D. Swanner; Nicholas Lambrecht; Chad Wittkop; Chris Harding; Sergei Katsev; Joshua Torgeson; Simon W. Poulton

doi:10.1016/j.earscirev.2020.103430

The biogeochemistry of ferruginous lakes and past ferruginous oceans

Elizabeth D. Swanner, Nicholas Lambrecht, Chad Wittkop, Chris Harding, Sergei Katsev, Joshua Torgeson, Simon W. Poulton

Physics & Astronomy (Duluth)

Research output: Contribution to journal › Review article › peer-review

36 Scopus citations

Abstract

Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere that occurred through most of the Archean Eon. While euxinic conditions (i.e. anoxic and hydrogen sulfide-rich waters) became more common in the Proterozoic, ferruginous conditions persisted in deep waters. Ferruginous ocean regions would have been a major biosphere and Earth surface reservoir through which elements passed through as part of their global biogeochemical cycles. Understanding key biological events, such as the rise of oxygen in the atmosphere, or even the transitions from ferruginous to euxinic or oxic conditions, requires understanding the biogeochemical processes occurring within ferruginous oceans, and their indicators in the rock record. Important analogs for transitions between ferruginous and oxic or euxinic conditions are paleoferruginous lakes; their sediments commonly host siderite and Ca-carbonates, which are important Precambrian records of the carbon cycling. Lakes that were ferruginous in the past, or euxinic lakes with cryptic iron cycling may also help understand transitions between ferruginous and euxinic conditions in shallow and mid-depth oceanic waters during the Proterozoic. Modern ferruginous meromictic lakes, which host diverse anaerobic microbial communities, are increasingly utilized as biogeochemical analogues for ancient ferruginous oceans. Such lakes are believed to be rare, but regional and geological factors indicate they may be more common than previously thought. While physical mixing processes in lakes and oceans are notably different, many chemical and biological processes are similar. The diversity of sizes, stratifications, and water chemistries in ferruginous lakes thus can be leveraged to explore biogeochemical controls in a range of marine systems: near-shore, off-shore, silled basins, or those dominated by terrestrial or hydrothermal element sources. Ferruginous systems, both extant and extinct, lacustrine and marine, host a continuum of biogeochemical processes that highlight the important role of iron in the evolution of Earth's surface environment.

Original language	English (US)
Article number	103430
Journal	Earth-Science Reviews
Volume	211
DOIs	https://doi.org/10.1016/j.earscirev.2020.103430
State	Published - Dec 2020

Bibliographical note

Funding Information:
Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant (EAR-1660691 to E. D. S. EAR-1660761 to C.W. and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake.

Funding Information:
Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant ( EAR-1660691 to E. D. S., EAR-1660761 to C.W., and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake.

Publisher Copyright:
© 2020

Keywords

(an)oxygenic photosynthesis
Ferruginous
Iron formation (IF)
Iron speciation
Meromictic
Siderite

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "The biogeochemistry of ferruginous lakes and past ferruginous oceans",

abstract = "Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere that occurred through most of the Archean Eon. While euxinic conditions (i.e. anoxic and hydrogen sulfide-rich waters) became more common in the Proterozoic, ferruginous conditions persisted in deep waters. Ferruginous ocean regions would have been a major biosphere and Earth surface reservoir through which elements passed through as part of their global biogeochemical cycles. Understanding key biological events, such as the rise of oxygen in the atmosphere, or even the transitions from ferruginous to euxinic or oxic conditions, requires understanding the biogeochemical processes occurring within ferruginous oceans, and their indicators in the rock record. Important analogs for transitions between ferruginous and oxic or euxinic conditions are paleoferruginous lakes; their sediments commonly host siderite and Ca-carbonates, which are important Precambrian records of the carbon cycling. Lakes that were ferruginous in the past, or euxinic lakes with cryptic iron cycling may also help understand transitions between ferruginous and euxinic conditions in shallow and mid-depth oceanic waters during the Proterozoic. Modern ferruginous meromictic lakes, which host diverse anaerobic microbial communities, are increasingly utilized as biogeochemical analogues for ancient ferruginous oceans. Such lakes are believed to be rare, but regional and geological factors indicate they may be more common than previously thought. While physical mixing processes in lakes and oceans are notably different, many chemical and biological processes are similar. The diversity of sizes, stratifications, and water chemistries in ferruginous lakes thus can be leveraged to explore biogeochemical controls in a range of marine systems: near-shore, off-shore, silled basins, or those dominated by terrestrial or hydrothermal element sources. Ferruginous systems, both extant and extinct, lacustrine and marine, host a continuum of biogeochemical processes that highlight the important role of iron in the evolution of Earth's surface environment.",

keywords = "(an)oxygenic photosynthesis, Ferruginous, Iron formation (IF), Iron speciation, Meromictic, Siderite",

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note = "Funding Information: Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant (EAR-1660691 to E. D. S. EAR-1660761 to C.W. and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake. Funding Information: Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant ( EAR-1660691 to E. D. S., EAR-1660761 to C.W., and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake. Publisher Copyright: {\textcopyright} 2020",

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T1 - The biogeochemistry of ferruginous lakes and past ferruginous oceans

AU - Swanner, Elizabeth D.

AU - Lambrecht, Nicholas

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AU - Torgeson, Joshua

AU - Poulton, Simon W.

N1 - Funding Information: Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant (EAR-1660691 to E. D. S. EAR-1660761 to C.W. and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake. Funding Information: Iowa State University subject librarian Jesse Garrison gave assistance in identifying the origin and historical usage of the word “ferruginous”. Anna Nesterovich provided assistance with data extraction from limnology papers in Russian. Sharon Koenig from the Minnesota Pollution Control Agency provided the well geochemistry data. Erik T. Brown generously provided XRF core scan Fe/Ti data from Lake Malawi. Annete von der Handt guided EPMA analysis. The University of Minnesota Continental Scientific Drilling and Coordination Office (LacCore, NSF-1338322) provided access to Lake Malawi and Otter Lake cores. This work was supported by the National Science Foundation (NSF) collaborative research grant ( EAR-1660691 to E. D. S., EAR-1660761 to C.W., and EAR-1660873 to S. K.) The Huron Mountain Wildlife Foundation (HMWF) provided housing and access to Canyon Lake. The Minneapolis Parks and Recreation Board provided access to Brownie Lake. Publisher Copyright: © 2020

PY - 2020/12

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N2 - Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere that occurred through most of the Archean Eon. While euxinic conditions (i.e. anoxic and hydrogen sulfide-rich waters) became more common in the Proterozoic, ferruginous conditions persisted in deep waters. Ferruginous ocean regions would have been a major biosphere and Earth surface reservoir through which elements passed through as part of their global biogeochemical cycles. Understanding key biological events, such as the rise of oxygen in the atmosphere, or even the transitions from ferruginous to euxinic or oxic conditions, requires understanding the biogeochemical processes occurring within ferruginous oceans, and their indicators in the rock record. Important analogs for transitions between ferruginous and oxic or euxinic conditions are paleoferruginous lakes; their sediments commonly host siderite and Ca-carbonates, which are important Precambrian records of the carbon cycling. Lakes that were ferruginous in the past, or euxinic lakes with cryptic iron cycling may also help understand transitions between ferruginous and euxinic conditions in shallow and mid-depth oceanic waters during the Proterozoic. Modern ferruginous meromictic lakes, which host diverse anaerobic microbial communities, are increasingly utilized as biogeochemical analogues for ancient ferruginous oceans. Such lakes are believed to be rare, but regional and geological factors indicate they may be more common than previously thought. While physical mixing processes in lakes and oceans are notably different, many chemical and biological processes are similar. The diversity of sizes, stratifications, and water chemistries in ferruginous lakes thus can be leveraged to explore biogeochemical controls in a range of marine systems: near-shore, off-shore, silled basins, or those dominated by terrestrial or hydrothermal element sources. Ferruginous systems, both extant and extinct, lacustrine and marine, host a continuum of biogeochemical processes that highlight the important role of iron in the evolution of Earth's surface environment.

AB - Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere that occurred through most of the Archean Eon. While euxinic conditions (i.e. anoxic and hydrogen sulfide-rich waters) became more common in the Proterozoic, ferruginous conditions persisted in deep waters. Ferruginous ocean regions would have been a major biosphere and Earth surface reservoir through which elements passed through as part of their global biogeochemical cycles. Understanding key biological events, such as the rise of oxygen in the atmosphere, or even the transitions from ferruginous to euxinic or oxic conditions, requires understanding the biogeochemical processes occurring within ferruginous oceans, and their indicators in the rock record. Important analogs for transitions between ferruginous and oxic or euxinic conditions are paleoferruginous lakes; their sediments commonly host siderite and Ca-carbonates, which are important Precambrian records of the carbon cycling. Lakes that were ferruginous in the past, or euxinic lakes with cryptic iron cycling may also help understand transitions between ferruginous and euxinic conditions in shallow and mid-depth oceanic waters during the Proterozoic. Modern ferruginous meromictic lakes, which host diverse anaerobic microbial communities, are increasingly utilized as biogeochemical analogues for ancient ferruginous oceans. Such lakes are believed to be rare, but regional and geological factors indicate they may be more common than previously thought. While physical mixing processes in lakes and oceans are notably different, many chemical and biological processes are similar. The diversity of sizes, stratifications, and water chemistries in ferruginous lakes thus can be leveraged to explore biogeochemical controls in a range of marine systems: near-shore, off-shore, silled basins, or those dominated by terrestrial or hydrothermal element sources. Ferruginous systems, both extant and extinct, lacustrine and marine, host a continuum of biogeochemical processes that highlight the important role of iron in the evolution of Earth's surface environment.

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KW - Iron formation (IF)

KW - Iron speciation

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The biogeochemistry of ferruginous lakes and past ferruginous oceans

Abstract

Bibliographical note

Keywords

UN SDGs

Access

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