Advertisement
GET OUR E-ALERTS
No access
Report

Redox Stabilization of the Atmosphere and Oceans by Phosphorus-Limited Marine Productivity

Philippe Van Cappellen and Ellery D. IngallAuthors Info & Affiliations
Science
26 Jan 1996
Vol 271, Issue 5248
pp. 493-496
DOI: 10.1126/science.271.5248.493
CHECK ACCESS

Abstract

Data from modern and ancient marine sediments demonstrate that burial of the limiting nutrient phosphorus is less efficient when bottom waters are low in oxygen. Mass-balance calculations using a coupled model of the biogeochemical cycles of carbon, phosphorus, oxygen, and iron indicate that the redox dependence of phosphorus burial in the oceans provides a powerful forcing mechanism for balancing production and consumption of atmospheric oxygen over geologic time. The oxygen-phosphorus coupling further guards against runaway ocean anoxia. Phosphorus-mediated redox stabilization of the atmosphere and oceans may have been crucial to the radiation of higher life forms during the Phanerozoic.

Get full access to this article

View all available purchase options and get full access to this article.

CHECK ACCESS

References

1
BERKNER V. L., ON ORIGIN AND RISE OF OXYGEN CONCENTRATION IN EARTHS ATMOSPHERE, JOURNAL OF THE ATMOSPHERIC SCIENCES 22, 225 (1965).
Google Scholar
2
BERNER A. R., MODELS FOR CARBON AND SULFUR CYCLES AND ATMOSPHERIC OXYGEN - APPLICATION TO PALEOZOIC GEOLOGIC HISTORY, AMERICAN JOURNAL OF SCIENCE 287, 177 (1987).
Google Scholar
3
BERNER A. R., A NEW MODEL FOR ATMOSPHERIC OXYGEN OVER PHANEROZOIC TIME, AMERICAN JOURNAL OF SCIENCE 289, 333 (1989).
Google Scholar
4
BERNER A. R., PALAEOGEOGR PALAEOCL 75, 97 (1989).
Google Scholar
5
BROECKER S. W., OCEAN CHEMISTRY DURING GLACIAL TIME, GEOCHIMICA ET COSMOCHIMICA ACTA 46, 1689 (1982).
Google Scholar
6
BROECKER S. W., TRACERS SEA (1982).
Google Scholar
7
CANFIELD E. D., SULFATE REDUCTION AND OXIC RESPIRATION IN MARINE-SEDIMENTS - IMPLICATIONS FOR ORGANIC-CARBON PRESERVATION IN EUXINIC ENVIRONMENTS, DEEP-SEA RESEARCH PART A-OCEANOGRAPHIC RESEARCH PAPERS 36, 121 (1989).
Google Scholar
8
FILIPPELLI M. G., THE OCEANIC PHOSPHORUS CYCLE AND CONTINENTAL WEATHERING DURING THE NEOGENE, PALEOCEANOGRAPHY 9, 643 (1994).
Google Scholar
9
FOLLMI B. K., 160 MY RECORD OF MARINE SEDIMENTARY PHOSPHORUS BURIAL - COUPLING OF CLIMATE AND CONTINENTAL WEATHERING UNDER GREENHOUSE AND ICEHOUSE CONDITIONS, GEOLOGY 23, 859 (1995).
Google Scholar
10
HERBERT D. T., OCEAN NUTRIENT DISTRIBUTION AND OXYGENATION - LIMITS ON THE FORMATION OF WARM SALINE BOTTOM WATER OVER THE PAST 91 MY, GEOLOGY 19, 702 (1991).
Google Scholar
11
HOLLAND D. H., CHEM ATMOSPHERE OCEA (1978).
Google Scholar
12
HOLLAND D. H., CHEM EVOLUTION ATMOS (1984).
Google Scholar
13
HOLLAND D. H., ATMOSPHERIC EVOLUTION - ORIGINS OF BREATHABLE AIR, NATURE 347, 17 (1990).
Google Scholar
14
INGALL E, EVIDENCE FOR ENHANCED PHOSPHORUS REGENERATION FROM MARINE-SEDIMENTS OVERLAIN BY OXYGEN DEPLETED WATERS, GEOCHIMICA ET COSMOCHIMICA ACTA 58, 2571 (1994).
Google Scholar
15
INGALL E, IN PRESS MAR GEOL .
Google Scholar
16
INGALL D. E., INFLUENCE OF WATER COLUMN ANOXIA ON THE BURIAL AND PRESERVATION OF CARBON AND PHOSPHORUS IN MARINE SHALES, GEOCHIMICA ET COSMOCHIMICA ACTA 57, 303 (1993).
Google Scholar
17
JONES P. T., PALAEOGEOGR PALAEOCL 77, 51 (1978).
Google Scholar
18
JONES P. T., PALAEOGEOGR PALAEOCL 77, 39 (1991).
Google Scholar
19
KUMP R. L., MODELING ATMOSPHERIC O-2 IN THE GLOBAL SEDIMENTARY REDOX CYCLE, AMERICAN JOURNAL OF SCIENCE 286, 337 (1986).
Google Scholar
20
KUMP R. L., INTERACTIONS C N P S: 475 (1993).
Google Scholar
21
KUMP R. L., TERRESTRIAL FEEDBACK IN ATMOSPHERIC OXYGEN REGULATION BY FIRE AND PHOSPHORUS, NATURE 335, 152 (1988).
Google Scholar
22
LASAGA C. A., CARBON CYCLE ATMOSPH: 397 (1985).
Google Scholar
23
REDFIELD C. A., THE BIOLOGICAL CONTROL OF CHEMICAL FACTORS IN THE ENVIRONMENT, AMERICAN SCIENTIST 46, 205 (1958).
Google Scholar
24
SARMIENTO L. J., GLOBAL BIOGEOCHEMICA 2, 115 (1988).
Google Scholar
25
TROMP K. T., A GLOBAL-MODEL FOR THE EARLY DIAGENESIS OF ORGANIC-CARBON AND ORGANIC PHOSPHORUS IN MARINE-SEDIMENTS, GEOCHIMICA ET COSMOCHIMICA ACTA 59, 1259 (1995).
Google Scholar
26
VANCAPPELLEN P, BENTHIC PHOSPHORUS REGENERATION, NET PRIMARY PRODUCTION, AND OCEAN ANOXIA - A MODEL OF THE COUPLED MARINE BIOGEOCHEMICAL CYCLES OF CARBON AND PHOSPHORUS, PALEOCEANOGRAPHY 9, 677 (1994).
Google Scholar
27
WATSON A, METHANOGENESIS, FIRES AND THE REGULATION OF ATMOSPHERIC OXYGEN, BIOSYSTEMS 10, 293 (1978).
Google Scholar

(0)eLetters

eLetters is a forum for ongoing peer review. eLetters are not edited, proofread, or indexed, but they are screened. eLetters should provide substantive and scholarly commentary on the article. Embedded figures cannot be submitted, and we discourage the use of figures within eLetters in general. If a figure is essential, please include a link to the figure within the text of the eLetter. Please read our Terms of Service before submitting an eLetter.

Log In to Submit a Response

No eLetters have been published for this article yet.

Information & Authors

Information

Published In

Science
Volume 271 | Issue 5248
26 January 1996

Copyright

© 1996 American Association for the Advancement of Science.

Submission history

Published in print: 26 January 1996

Permissions

Request permissions for this article.

Authors

Affiliations

Philippe Van Cappellen(1)
P. Van Cappellen, School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, GA 30332-0340, USA.
View all articles by this author
Ellery D. Ingall
E. D. Ingall, Marine Science Institute, University of Texas at Austin, Port Aransas, TX 78373-1267, USA.
View all articles by this author

Notes

(1)
To whom correspondence should be addressed.

Metrics & Citations

Metrics

Article Usage

Note: The article usage is presented with a three- to four-day delay and will update daily once available. Due to this delay, usage data will not appear immediately following publication.

Citation information is sourced from Crossref Cited-by service.

Altmetrics

Citations

Cite as

  • Philippe Van Cappellen,
  • Ellery D. Ingall
,
Redox Stabilization of the Atmosphere and Oceans by Phosphorus-Limited Marine Productivity.Science271,493-496(1996).DOI:10.1126/science.271.5248.493

Export citation

Select the format you want to export the citation of this publication.

Cited by

    • Nina M. Papadomanolaki,
    • Wytze K. Lenstra,
    • Mariette Wolthers,
    • Caroline P. Slomp,
    Enhanced phosphorus recycling during past oceanic anoxia amplified by low rates of apatite authigenesis, Science Advances, 8, 26, (2022)./doi/10.1126/sciadv.abn2370
    Abstract
    • Darcy L. McRose,
    • Dianne K. Newman,
    Redox-active antibiotics enhance phosphorus bioavailability, Science, 371, 6533, (1033-1037), (2021)./doi/10.1126/science.abd1515
    Abstract
    • Claudia Benitez-Nelson,
    The missing link in oceanic phosphorus cycling?, Science, 348, 6236, (759-760), (2021)./doi/10.1126/science.aab2801
    Abstract
    • Adina Paytan,
    • Miriam Kastner,
    • Douglas Campbell,
    • Mark H. Thiemens,
    Seawater Sulfur Isotope Fluctuations in the Cretaceous, Science, 304, 5677, (1663-1665), (2021)./doi/10.1126/science.1095258
    Abstract
    • Nemanja Komar,
    • Richard E. Zeebe,
    Reconciling atmospheric CO2, weathering, and calcite compensation depth across the Cenozoic, Science Advances, 7, 4, (2021)./doi/10.1126/sciadv.abd4876
    Abstract
    • Feifei Zhang,
    • Stephen J. Romaniello,
    • Thomas J. Algeo,
    • Kimberly V. Lau,
    • Matthew E. Clapham,
    • Sylvain Richoz,
    • Achim D. Herrmann,
    • Harrison Smith,
    • Micha Horacek,
    • Ariel D. Anbar,
    Multiple episodes of extensive marine anoxia linked to global warming and continental weathering following the latest Permian mass extinction, Science Advances, 4, 4, (2018)./doi/10.1126/sciadv.1602921
    Abstract
    • D. A. Stolper,
    • M. L. Bender,
    • G. B. Dreyfus,
    • Y. Yan,
    • J. A. Higgins,
    A Pleistocene ice core record of atmospheric O2 concentrations, Science, 353, 6306, (1427-1430), (2016)./doi/10.1126/science.aaf5445
    Abstract
    • Markus A. Keller,
    • Andre Zylstra,
    • Cecilia Castro,
    • Alexandra V. Turchyn,
    • Julian L. Griffin,
    • Markus Ralser,
    Conditional iron and pH-dependent activity of a non-enzymatic glycolysis and pentose phosphate pathway, Science Advances, 2, 1, (2016)./doi/10.1126/sciadv.1501235
    Abstract
    • Julia Diaz,
    • Ellery Ingall,
    • Claudia Benitez-Nelson,
    • David Paterson,
    • Martin D. de Jonge,
    • Ian McNulty,
    • Jay A. Brandes,
    Marine Polyphosphate: A Key Player in Geologic Phosphorus Sequestration, Science, 320, 5876, (652-655), (2008)./doi/10.1126/science.1151751
    Abstract
    • Adina Paytan,
    • Miriam Kastner,
    • Douglas Campbell,
    • Mark H. Thiemens,
    Sulfur Isotopic Composition of Cenozoic Seawater Sulfate, Science, 282, 5393, (1459-1462), (1998)./doi/10.1126/science.282.5393.1459
    Abstract
  11. See more

Citation information is sourced from Crossref Cited-by service.

View Options

Check Access

Log in to view the full text

AAAS ID LOGIN

AAAS login provides access to Science for AAAS Members, and access to other journals in the Science family to users who have purchased individual subscriptions.

Log in via OpenAthens.
via OpenAthens
Log in via Shibboleth.
via Shibboleth

More options

Purchase digital access to this article

Download and print this article for your personal scholarly, research, and educational use.

Purchase this issue in print

Buy a single issue of Science for just $15 USD.

View options

PDF format

Download this article as a PDF file

Download PDF

Media

Figures

Multimedia

Tables

Share

Share

Share article link

Share on social media