Sustained climate warming drives declining marine biological productivity

J. Keith Moore; Weiwei Fu; Francois Primeau; Gregory L. Britten; Keith Lindsay; Matthew Long; Scott C. Doney; Natalie Mahowald; Forrest Hoffman; James T. Randerson

doi:10.1126/science.aao6379

Sustained climate warming drives declining marine biological productivity

J. Keith Moore, Weiwei Fu, Francois Primeau, Gregory L. Britten, Keith Lindsay, Matthew Long, Scott C. Doney, Natalie Mahowald, Forrest Hoffman, James T. Randerson

CGD

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348 Scopus citations

Abstract

Climate change projections to the year 2100 may miss physical-biogeochemical feedbacks that emerge later from the cumulative effects of climate warming. In a coupled climate simulation to the year 2300, the westerly winds strengthen and shift poleward, surface waters warm, and sea ice disappears, leading to intense nutrient trapping in the Southern Ocean. The trapping drives a global-scale nutrient redistribution, with net transfer to the deep ocean. Ensuing surface nutrient reductions north of 30°S drive steady declines in primary production and carbon export (decreases of 24 and 41%, respectively, by 2300). Potential fishery yields, constrained by lower–trophic-level productivity, decrease by more than 20% globally and by nearly 60% in the North Atlantic. Continued high levels of greenhouse gas emissions could suppress marine biological productivity for a millennium.

Original language	English
Pages (from-to)	113-1143
Number of pages	1031
Journal	Science
Volume	359
Issue number	6380
DOIs	https://doi.org/10.1126/science.aao6379
State	Published - Mar 9 2018

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title = "Sustained climate warming drives declining marine biological productivity",

abstract = "Climate change projections to the year 2100 may miss physical-biogeochemical feedbacks that emerge later from the cumulative effects of climate warming. In a coupled climate simulation to the year 2300, the westerly winds strengthen and shift poleward, surface waters warm, and sea ice disappears, leading to intense nutrient trapping in the Southern Ocean. The trapping drives a global-scale nutrient redistribution, with net transfer to the deep ocean. Ensuing surface nutrient reductions north of 30°S drive steady declines in primary production and carbon export (decreases of 24 and 41\%, respectively, by 2300). Potential fishery yields, constrained by lower–trophic-level productivity, decrease by more than 20\% globally and by nearly 60\% in the North Atlantic. Continued high levels of greenhouse gas emissions could suppress marine biological productivity for a millennium.",

author = "\{Keith Moore\}, J. and Weiwei Fu and Francois Primeau and Britten, \{Gregory L.\} and Keith Lindsay and Matthew Long and Doney, \{Scott C.\} and Natalie Mahowald and Forrest Hoffman and Randerson, \{James T.\}",

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doi = "10.1126/science.aao6379",

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T1 - Sustained climate warming drives declining marine biological productivity

AU - Keith Moore, J.

AU - Fu, Weiwei

AU - Primeau, Francois

AU - Britten, Gregory L.

AU - Lindsay, Keith

AU - Long, Matthew

AU - Doney, Scott C.

AU - Mahowald, Natalie

AU - Hoffman, Forrest

AU - Randerson, James T.

PY - 2018/3/9

Y1 - 2018/3/9

N2 - Climate change projections to the year 2100 may miss physical-biogeochemical feedbacks that emerge later from the cumulative effects of climate warming. In a coupled climate simulation to the year 2300, the westerly winds strengthen and shift poleward, surface waters warm, and sea ice disappears, leading to intense nutrient trapping in the Southern Ocean. The trapping drives a global-scale nutrient redistribution, with net transfer to the deep ocean. Ensuing surface nutrient reductions north of 30°S drive steady declines in primary production and carbon export (decreases of 24 and 41%, respectively, by 2300). Potential fishery yields, constrained by lower–trophic-level productivity, decrease by more than 20% globally and by nearly 60% in the North Atlantic. Continued high levels of greenhouse gas emissions could suppress marine biological productivity for a millennium.

AB - Climate change projections to the year 2100 may miss physical-biogeochemical feedbacks that emerge later from the cumulative effects of climate warming. In a coupled climate simulation to the year 2300, the westerly winds strengthen and shift poleward, surface waters warm, and sea ice disappears, leading to intense nutrient trapping in the Southern Ocean. The trapping drives a global-scale nutrient redistribution, with net transfer to the deep ocean. Ensuing surface nutrient reductions north of 30°S drive steady declines in primary production and carbon export (decreases of 24 and 41%, respectively, by 2300). Potential fishery yields, constrained by lower–trophic-level productivity, decrease by more than 20% globally and by nearly 60% in the North Atlantic. Continued high levels of greenhouse gas emissions could suppress marine biological productivity for a millennium.

UR - https://www.scopus.com/pages/publications/85043272469

U2 - 10.1126/science.aao6379

DO - 10.1126/science.aao6379

M3 - Article

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AN - SCOPUS:85043272469

SN - 0036-8075

VL - 359

SP - 113

EP - 1143

JO - Science

JF - Science

IS - 6380

ER -

Sustained climate warming drives declining marine biological productivity

Abstract

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