Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation

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Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation. / Boyle, Richard; Dahl, Tais Wittchen; Dale, A. W.; Shields-Zhou, G. A.; Zhu, M.; Brasier, M. D.; Canfield, D. E.; Lenton, T. M.

In: Nature Geoscience, Vol. 7, No. 9, 2014, p. 671-676.

Research output: Contribution to journalLetterResearchpeer-review

Harvard

Boyle, R, Dahl, TW, Dale, AW, Shields-Zhou, GA, Zhu, M, Brasier, MD, Canfield, DE & Lenton, TM 2014, 'Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation', Nature Geoscience, vol. 7, no. 9, pp. 671-676. https://doi.org/10.1038/NGEO2213

APA

Boyle, R., Dahl, T. W., Dale, A. W., Shields-Zhou, G. A., Zhu, M., Brasier, M. D., Canfield, D. E., & Lenton, T. M. (2014). Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation. Nature Geoscience, 7(9), 671-676. https://doi.org/10.1038/NGEO2213

Vancouver

Boyle R, Dahl TW, Dale AW, Shields-Zhou GA, Zhu M, Brasier MD et al. Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation. Nature Geoscience. 2014;7(9):671-676. https://doi.org/10.1038/NGEO2213

Author

Boyle, Richard ; Dahl, Tais Wittchen ; Dale, A. W. ; Shields-Zhou, G. A. ; Zhu, M. ; Brasier, M. D. ; Canfield, D. E. ; Lenton, T. M. / Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation. In: Nature Geoscience. 2014 ; Vol. 7, No. 9. pp. 671-676.

Bibtex

@article{a06883b1d9e64e41b1d7b244331d129a,
title = "Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation",
abstract = "Animal burrowing and sediment-mixing (bioturbation) began during the run up to the Ediacaran/Cambrian boundary1,2,3, initiating a transition4,5 between the stratified Precambrian6 and more well-mixed Phanerozoic7 sedimentary records, against the backdrop of a variable8,9 global oxygen reservoir probably smaller in size than present10,11. Phosphorus is the long-term12 limiting nutrient for oxygen production via burial of organic carbon13, and its retention (relative to carbon) within organic matter in marine sediments is enhanced by bioturbation14,15,16,17,18. Here we explore the biogeochemical implications of a bioturbation-induced organic phosphorus sink in a simple model. We show that increased bioturbation robustly triggers a net decrease in the size of the global oxygen reservoir—the magnitude of which is contingent upon the prescribed difference in carbon to phosphorus ratios between bioturbated and laminated sediments. Bioturbation also reduces steady-state marine phosphate levels, but this effect is offset by the decline in iron-adsorbed phosphate burial that results from a decrease in oxygen concentrations. The introduction of oxygen-sensitive bioturbation to dynamical model runs is sufficient to trigger a negative feedback loop: the intensity of bioturbation is limited by the oxygen decrease it initially causes. The onset of this feedback is consistent with redox variations observed during the early Cambrian rise of bioturbation, leading us to suggest that bioturbation helped to regulate early oxygen and phosphorus cycles.",
author = "Richard Boyle and Dahl, {Tais Wittchen} and Dale, {A. W.} and Shields-Zhou, {G. A.} and M. Zhu and Brasier, {M. D.} and Canfield, {D. E.} and Lenton, {T. M.}",
year = "2014",
doi = "10.1038/NGEO2213",
language = "English",
volume = "7",
pages = "671--676",
journal = "Nature Geoscience",
issn = "1752-0894",
publisher = "nature publishing group",
number = "9",

}

RIS

TY - JOUR

T1 - Stabilization of the coupled oxygen and phosphorus cycles by the evolution of bioturbation

AU - Boyle, Richard

AU - Dahl, Tais Wittchen

AU - Dale, A. W.

AU - Shields-Zhou, G. A.

AU - Zhu, M.

AU - Brasier, M. D.

AU - Canfield, D. E.

AU - Lenton, T. M.

PY - 2014

Y1 - 2014

N2 - Animal burrowing and sediment-mixing (bioturbation) began during the run up to the Ediacaran/Cambrian boundary1,2,3, initiating a transition4,5 between the stratified Precambrian6 and more well-mixed Phanerozoic7 sedimentary records, against the backdrop of a variable8,9 global oxygen reservoir probably smaller in size than present10,11. Phosphorus is the long-term12 limiting nutrient for oxygen production via burial of organic carbon13, and its retention (relative to carbon) within organic matter in marine sediments is enhanced by bioturbation14,15,16,17,18. Here we explore the biogeochemical implications of a bioturbation-induced organic phosphorus sink in a simple model. We show that increased bioturbation robustly triggers a net decrease in the size of the global oxygen reservoir—the magnitude of which is contingent upon the prescribed difference in carbon to phosphorus ratios between bioturbated and laminated sediments. Bioturbation also reduces steady-state marine phosphate levels, but this effect is offset by the decline in iron-adsorbed phosphate burial that results from a decrease in oxygen concentrations. The introduction of oxygen-sensitive bioturbation to dynamical model runs is sufficient to trigger a negative feedback loop: the intensity of bioturbation is limited by the oxygen decrease it initially causes. The onset of this feedback is consistent with redox variations observed during the early Cambrian rise of bioturbation, leading us to suggest that bioturbation helped to regulate early oxygen and phosphorus cycles.

AB - Animal burrowing and sediment-mixing (bioturbation) began during the run up to the Ediacaran/Cambrian boundary1,2,3, initiating a transition4,5 between the stratified Precambrian6 and more well-mixed Phanerozoic7 sedimentary records, against the backdrop of a variable8,9 global oxygen reservoir probably smaller in size than present10,11. Phosphorus is the long-term12 limiting nutrient for oxygen production via burial of organic carbon13, and its retention (relative to carbon) within organic matter in marine sediments is enhanced by bioturbation14,15,16,17,18. Here we explore the biogeochemical implications of a bioturbation-induced organic phosphorus sink in a simple model. We show that increased bioturbation robustly triggers a net decrease in the size of the global oxygen reservoir—the magnitude of which is contingent upon the prescribed difference in carbon to phosphorus ratios between bioturbated and laminated sediments. Bioturbation also reduces steady-state marine phosphate levels, but this effect is offset by the decline in iron-adsorbed phosphate burial that results from a decrease in oxygen concentrations. The introduction of oxygen-sensitive bioturbation to dynamical model runs is sufficient to trigger a negative feedback loop: the intensity of bioturbation is limited by the oxygen decrease it initially causes. The onset of this feedback is consistent with redox variations observed during the early Cambrian rise of bioturbation, leading us to suggest that bioturbation helped to regulate early oxygen and phosphorus cycles.

U2 - 10.1038/NGEO2213

DO - 10.1038/NGEO2213

M3 - Letter

VL - 7

SP - 671

EP - 676

JO - Nature Geoscience

JF - Nature Geoscience

SN - 1752-0894

IS - 9

ER -

ID: 132389883