Multi-faceted particle pumps drive carbon sequestration in the ocean

The ocean’s ability to sequester carbon away from the atmosphere exerts an important control on global climate. The biological pump drives carbon storage in the deep ocean and is thought to function via gravitational settling of organic particles from surface waters. However, the settling flux alone...

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Veröffentlicht in:	Nature (London) 2019-04, Vol.568 (7752), p.327-335
Hauptverfasser:	Boyd, Philip W., Claustre, Hervé, Levy, Marina, Siegel, David A., Weber, Thomas
Format:	Artikel
Sprache:	eng
Schlagworte:	631/158/2446/2447 704/829/827 Aquatic Organisms - metabolism Atmosphere Atmosphere - chemistry Biogeochemistry Biota Budget deficits Budgets Carbon Carbon - analysis Carbon - chemistry Carbon budget Carbon dioxide Carbon Dioxide - analysis Carbon Dioxide - chemistry Carbon Dioxide - metabolism Carbon Sequestration Climate Efficiency Environmental control Estimates Exports Geophysics Global climate Gravitation Gravity Humanities and Social Sciences Marine accidents Methods multidisciplinary Neural networks Ocean circulation Oceans Oceans and Seas Optical properties Particle injection Pelagic zone Photosynthesis Physics Plankton Pumps Review review-article Science Science (multidisciplinary) Seawater - chemistry Settling Solubility Surface water
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creator	Boyd, Philip W. Claustre, Hervé Levy, Marina Siegel, David A. Weber, Thomas
description	The ocean’s ability to sequester carbon away from the atmosphere exerts an important control on global climate. The biological pump drives carbon storage in the deep ocean and is thought to function via gravitational settling of organic particles from surface waters. However, the settling flux alone is often insufficient to balance mesopelagic carbon budgets or to meet the demands of subsurface biota. Here we review additional biological and physical mechanisms that inject suspended and sinking particles to depth. We propose that these ‘particle injection pumps’ probably sequester as much carbon as the gravitational pump, helping to close the carbon budget and motivating further investigation into their environmental control. This Review discusses particle injection pumps, which inject suspended and sinking particles to different ocean depths and may sequester as much carbon as the biological gravitational pump.
doi_str_mv	10.1038/s41586-019-1098-2
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subjects	631/158/2446/2447 704/829/827 Aquatic Organisms - metabolism Atmosphere Atmosphere - chemistry Biogeochemistry Biota Budget deficits Budgets Carbon Carbon - analysis Carbon - chemistry Carbon budget Carbon dioxide Carbon Dioxide - analysis Carbon Dioxide - chemistry Carbon Dioxide - metabolism Carbon Sequestration Climate Efficiency Environmental control Estimates Exports Geophysics Global climate Gravitation Gravity Humanities and Social Sciences Marine accidents Methods multidisciplinary Neural networks Ocean circulation Oceans Oceans and Seas Optical properties Particle injection Pelagic zone Photosynthesis Physics Plankton Pumps Review review-article Science Science (multidisciplinary) Seawater - chemistry Settling Solubility Surface water
title	Multi-faceted particle pumps drive carbon sequestration in the ocean
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