Preformed phosphate, soft tissue pump and

by Takamitsu Ito 1,2 and Michael J. Follows 1 We develop a new theory relating atmospheric pCO 2 and the efficiency of the soft tissue pump of CO 2 in the ocean, measured by P*, a quasi-conservative tracer. P * is inversely correlated with preformed phosphate, and its global average represents the f...

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Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
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Southern Ocean
Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.397.8477
http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf
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spelling ftciteseerx:oai:CiteSeerX.psu:10.1.1.397.8477 2023-05-15T18:25:44+02:00 Preformed phosphate, soft tissue pump and The Pennsylvania State University CiteSeerX Archives application/pdf http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.397.8477 http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf en eng http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.397.8477 http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf Metadata may be used without restrictions as long as the oai identifier remains attached to it. http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf text ftciteseerx 2016-09-25T00:08:53Z by Takamitsu Ito 1,2 and Michael J. Follows 1 We develop a new theory relating atmospheric pCO 2 and the efficiency of the soft tissue pump of CO 2 in the ocean, measured by P*, a quasi-conservative tracer. P * is inversely correlated with preformed phosphate, and its global average represents the fraction of nutrients transported by the export and remineralization of organic material. This view is combined with global conservation constraints for carbon and nutrients leading to a theoretical prediction for the sensitivity of atmospheric pCO 2 to changes in globally averaged P*. The theory is supported by sensitivity studies with a more complex, three-dimensional numerical simulations. The numerical experiments suggest that the ocean carbon cycle is unlikely to approach the theoretical limit where globally averaged P * � 1 (complete depletion of preformed phosphate) because the localized dynamics of deep water formation, which may be associated with rapid vertical mixing timescales, preclude the ventilation of strongly nutrient-depleted waters. Hence, in the large volume of the deep waters of the ocean, it is difficult to significantly reduce preformed nutrient (or increase P*) by increasing the efficiency of export production. This mechanism could ultimately control the efficiency of biological pumps in a climate with increased aeolian iron sources to the Southern Ocean. Using these concepts we can reconcile qualitative differences in the response of atmospheric pCO 2 to surface nutrient draw down in highly idealized box models and more complex, general circulation models. We suggest that studies of carbon cycle dynamics in regions of deep water formation are the key to understanding the sensitivity of atmospheric pCO 2 to biological pumps in the ocean. 1. Text Southern Ocean Unknown Southern Ocean
institution Open Polar
collection Unknown
op_collection_id ftciteseerx
language English
description by Takamitsu Ito 1,2 and Michael J. Follows 1 We develop a new theory relating atmospheric pCO 2 and the efficiency of the soft tissue pump of CO 2 in the ocean, measured by P*, a quasi-conservative tracer. P * is inversely correlated with preformed phosphate, and its global average represents the fraction of nutrients transported by the export and remineralization of organic material. This view is combined with global conservation constraints for carbon and nutrients leading to a theoretical prediction for the sensitivity of atmospheric pCO 2 to changes in globally averaged P*. The theory is supported by sensitivity studies with a more complex, three-dimensional numerical simulations. The numerical experiments suggest that the ocean carbon cycle is unlikely to approach the theoretical limit where globally averaged P * � 1 (complete depletion of preformed phosphate) because the localized dynamics of deep water formation, which may be associated with rapid vertical mixing timescales, preclude the ventilation of strongly nutrient-depleted waters. Hence, in the large volume of the deep waters of the ocean, it is difficult to significantly reduce preformed nutrient (or increase P*) by increasing the efficiency of export production. This mechanism could ultimately control the efficiency of biological pumps in a climate with increased aeolian iron sources to the Southern Ocean. Using these concepts we can reconcile qualitative differences in the response of atmospheric pCO 2 to surface nutrient draw down in highly idealized box models and more complex, general circulation models. We suggest that studies of carbon cycle dynamics in regions of deep water formation are the key to understanding the sensitivity of atmospheric pCO 2 to biological pumps in the ocean. 1.
author2 The Pennsylvania State University CiteSeerX Archives
format Text
title Preformed phosphate, soft tissue pump and
spellingShingle Preformed phosphate, soft tissue pump and
title_short Preformed phosphate, soft tissue pump and
title_full Preformed phosphate, soft tissue pump and
title_fullStr Preformed phosphate, soft tissue pump and
title_full_unstemmed Preformed phosphate, soft tissue pump and
title_sort preformed phosphate, soft tissue pump and
url http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.397.8477
http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf
geographic Southern Ocean
geographic_facet Southern Ocean
genre Southern Ocean
genre_facet Southern Ocean
op_source http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf
op_relation http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.397.8477
http://ocean.mit.edu/~mick/Papers/ItoFollows-preformed-JMR2005.pdf
op_rights Metadata may be used without restrictions as long as the oai identifier remains attached to it.
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