Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans

Research output: Contribution to journalJournal articleResearch

Standard

Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans. / Posth, Nicole R.; Hegler, Florian; Konhauser, Kurt O.; Kappler, Andreas.

In: Nature Geosciences, 07.10.2008, p. 703-708.

Research output: Contribution to journalJournal articleResearch

Harvard

Posth, NR, Hegler, F, Konhauser, KO & Kappler, A 2008, 'Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans', Nature Geosciences, pp. 703-708. https://doi.org/10.1038/ngeo306

APA

Posth, N. R., Hegler, F., Konhauser, K. O., & Kappler, A. (2008). Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans. Nature Geosciences, 703-708. https://doi.org/10.1038/ngeo306

Vancouver

Posth NR, Hegler F, Konhauser KO, Kappler A. Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans. Nature Geosciences. 2008 Oct 7;703-708. https://doi.org/10.1038/ngeo306

Author

Posth, Nicole R. ; Hegler, Florian ; Konhauser, Kurt O. ; Kappler, Andreas. / Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans. In: Nature Geosciences. 2008 ; pp. 703-708.

Bibtex

@article{876721b08de748d8a10f2aaaeef83eee,
title = "Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans",
abstract = "Precambrian banded iron formations provide an extensive archive of pivotal environmental changes and the evolution of biological processes on early Earth. The formations are characterized by bands ranging from micrometre- to metre-scale layers of alternating iron- and silica-rich minerals. However, the nature of the mechanisms of layer formation is unknown. To properly evaluate this archive, the physical, chemical and/or biological triggers for the deposition of both the iron- and silica-rich layers, and crucially their alternate banding, must be identified. Here we use laboratory experiments and geochemical modelling to study the potential for a microbial mechanism in the formation of alternating iron–silica bands. We find that the rate of biogenic iron(III) mineral formation by iron-oxidizing microbes reaches a maximum between 20 and 25 °C. Decreasing or increasing water temperatures slow microbial iron mineral formation while promoting abiotic silica precipitation. We suggest that natural fluctuations in the temperature of the ocean photic zone during the period when banded iron formations were deposited could have led to the primary layering observed in these formations by successive cycles of microbially catalysed iron(III) mineral deposition and abiotic silica precipitation.",
author = "Posth, {Nicole R.} and Florian Hegler and Konhauser, {Kurt O.} and Andreas Kappler",
year = "2008",
month = oct,
day = "7",
doi = "10.1038/ngeo306",
language = "English",
pages = "703--708",
journal = "Nature Geoscience",
issn = "1752-0894",
publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Alternating Si and Fe deposition caused by temperature fluctuations in Precambrian oceans

AU - Posth, Nicole R.

AU - Hegler, Florian

AU - Konhauser, Kurt O.

AU - Kappler, Andreas

PY - 2008/10/7

Y1 - 2008/10/7

N2 - Precambrian banded iron formations provide an extensive archive of pivotal environmental changes and the evolution of biological processes on early Earth. The formations are characterized by bands ranging from micrometre- to metre-scale layers of alternating iron- and silica-rich minerals. However, the nature of the mechanisms of layer formation is unknown. To properly evaluate this archive, the physical, chemical and/or biological triggers for the deposition of both the iron- and silica-rich layers, and crucially their alternate banding, must be identified. Here we use laboratory experiments and geochemical modelling to study the potential for a microbial mechanism in the formation of alternating iron–silica bands. We find that the rate of biogenic iron(III) mineral formation by iron-oxidizing microbes reaches a maximum between 20 and 25 °C. Decreasing or increasing water temperatures slow microbial iron mineral formation while promoting abiotic silica precipitation. We suggest that natural fluctuations in the temperature of the ocean photic zone during the period when banded iron formations were deposited could have led to the primary layering observed in these formations by successive cycles of microbially catalysed iron(III) mineral deposition and abiotic silica precipitation.

AB - Precambrian banded iron formations provide an extensive archive of pivotal environmental changes and the evolution of biological processes on early Earth. The formations are characterized by bands ranging from micrometre- to metre-scale layers of alternating iron- and silica-rich minerals. However, the nature of the mechanisms of layer formation is unknown. To properly evaluate this archive, the physical, chemical and/or biological triggers for the deposition of both the iron- and silica-rich layers, and crucially their alternate banding, must be identified. Here we use laboratory experiments and geochemical modelling to study the potential for a microbial mechanism in the formation of alternating iron–silica bands. We find that the rate of biogenic iron(III) mineral formation by iron-oxidizing microbes reaches a maximum between 20 and 25 °C. Decreasing or increasing water temperatures slow microbial iron mineral formation while promoting abiotic silica precipitation. We suggest that natural fluctuations in the temperature of the ocean photic zone during the period when banded iron formations were deposited could have led to the primary layering observed in these formations by successive cycles of microbially catalysed iron(III) mineral deposition and abiotic silica precipitation.

U2 - 10.1038/ngeo306

DO - 10.1038/ngeo306

M3 - Journal article

SP - 703

EP - 708

JO - Nature Geoscience

JF - Nature Geoscience

SN - 1752-0894

ER -

ID: 347303616