Potential Impacts of Climate Interventions on Marine Ecosystems

Kelsey E. Roberts; Tyler Rohr; Morgan R. Raven; Michael S. Diamond; Daniele Visioni; Ben Kravitz; Ryan Heneghan; Colleen M. Petrik; Daniele Bianchi; Kelly Ortega-Cisneros; Monica A. Morrison; Vanessa van Heerden; Nicola A. Wiseman; Gouri Anil; Zachary J. Cannizzo; Marta Coll; Joshua Coupe; Ryan Freedman; Kristen Krumhardt; Lester Kwiatkowski; Nicole S. Lovenduski; Jessica Y. Luo; Holly C. Olivarez; Alan Robock; Jeroen Steenbeek; Cheryl S. Harrison

doi:10.1029/2024RG000876

Potential Impacts of Climate Interventions on Marine Ecosystems

Kelsey E. Roberts
, Tyler Rohr
, Morgan R. Raven
, Michael S. Diamond
, Daniele Visioni
, Ben Kravitz
, Ryan Heneghan
, Colleen M. Petrik
, Daniele Bianchi
, Kelly Ortega-Cisneros
, Monica A. Morrison
, Vanessa van Heerden
, Nicola A. Wiseman
, Gouri Anil
, Zachary J. Cannizzo
, Marta Coll
, Joshua Coupe
, Ryan Freedman
, Kristen Krumhardt
, Lester Kwiatkowski

Nicole S. Lovenduski, Jessica Y. Luo, Holly C. Olivarez, Alan Robock, Jeroen Steenbeek, Cheryl S. Harrison

Cornell University
Louisiana State University
University of Massachusetts Dartmouth
University of Tasmania
Australian Antarctic Program Partnership
University of California at Santa Barbara
Florida State University
Indiana University Bloomington
Pacific Northwest National Laboratory
Griffith University Queensland
University of California at San Diego
University of California at Los Angeles
University of Cape Town
National Center for Atmospheric Research
Louisiana Sea Grant College Program
University of Bristol
McHenry County Conservation District
National Oceanic and Atmospheric Administration
Ecopath International Initiative
CSIC - Institute of Marine Sciences of Andalusia
University of Colorado Boulder
University of Southern California
Sorbonne Université
University Corporation For Atmospheric Res
Rutgers - The State University of New Jersey, New Brunswick

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

Rising global temperatures pose significant risks to marine ecosystems, biodiversity, and fisheries. Recent comprehensive assessments suggest that large-scale mitigation efforts to limit warming are falling short, and all feasible future climate projections, including those that represent optimistic emissions reductions, exceed the Paris Agreement's 1.5°C or 2° warming targets during this century. While avoiding further CO₂ emissions remains the most effective way to prevent environmental destabilization, interest is growing in climate interventions—deliberate, large-scale manipulations of the environment aimed at reducing global warming. These include carbon dioxide removal (CDR) to reduce atmospheric CO₂ concentrations over time, and solar radiation modification (SRM), which reflects sunlight to lower surface temperatures but does not address root CO₂ causes. The effects of these interventions on marine ecosystems, both direct and in combination with ongoing climate change, remain highly uncertain. Given the ocean's central role in regulating Earth's climate and supporting global food security, understanding these potential effects is crucial. This review provides an overview of proposed intervention methodologies for marine CDR and SRM and outlines the potential trade-offs and knowledge gaps associated with their impacts on marine ecosystems. Climate interventions have the potential to reduce warming-driven impacts, but could also alter marine food systems, biodiversity and ecosystem function. Effects will vary by pathway, scale, and regional context. Pathway-specific impact assessments are thus crucial to quantify trade-offs between plausible intervention scenarios as well as to identify their expected impacts on marine ecosystems in order to prioritize scaling efforts for low-risk pathways and avoid high-risk scenarios.

Original language	English
Article number	e2024RG000876
Number of pages	42
Journal	Reviews of Geophysics
Volume	64
Issue number	1
DOIs	https://doi.org/10.1029/2024RG000876
State	Published - Jan 14 2026
Externally published	Yes

Funding

KER and CSH were supported by LSU, NOAA, and NSF award 2218777. TR is an ARC DECRA Recipient (DE240100115) funded by the Australian Government. MR is supported by funding to UCSB from the Grantham Foundation for the Protection of the Environment. MSD is supported by the NOAA Climate Program Office Earth's Radiation Budget (ERB), Atmospheric Chemistry, Carbon Cycle, & Climate (AC4), and Climate Variability & Predictability (CVP) Programs, Grant NA23OAR4310297. Support for KOC was provided by Schmidt Sciences, LLC. KK is supported by NOAA NOPP Grants NA23OAR0170515 and NA23OAR0170514. Support for BK was provided in part by NOAA's Climate Program Office, Earth's Radiation Budget (ERB) (Grant NA22OAR4310479), and the Indiana University Environmental Resilience Institute. Support for KER and DV was partly provided by the Quadrature Climate Foundation. The Pacific Northwest National Laboratory is operated for the US Department of Energy by Battelle Memorial Institute under contract DE-AC05-76RL01830. NSL acknowledges support from NSF (OCE-1752724). AR is supported by NSF Grant AGS-2017113. CP was supported by NOAA CPO MAPP NA20OAR4310438, NA20OAR4310441 and NA20OAR4310442. MC and JS were supported by the Spanish funded ProOceans (Ministerio de Ciencia e Innovacion, Proyectos de I + D + I, RETOS-PID2020-118097RB-I00), and MC was supported by GES4SEAS (European Union's Horizon 2020 research under grant agreement no. 101059877) project and the "Severo Ochoa Centre of Excellence" accreditation (CEX2019-000928-S) to the Institute of Marine Science (ICM-CSIC). Support for HO is provided by the NOAA Climate and Global Change Postdoctoral Fellowship Program, administered by UCAR's Cooperative Programs for the Advancement of Earth System Science (CPAESS) under the NOAA Science Collaboration Program Award NA23OAR4310383B. The authors are grateful to Dr. Kyung-Min Noh (NOAA GFDL) and Steve Gittings (NOAA ONMS) for their internal review.

Funders	Funder number
NSF	2218777, OCE-1752724, AGS-2017113
Atmospheric Chemistry, Carbon Cycle, Climate
NOAA Climate Program Office Earth's Radiation Budget	NA22OAR4310479, NA20OAR4310438, NA20OAR4310441, NA20OAR4310442, NA23OAR0170515, NA23OAR0170514, NA23OAR4310383B
NOPP
UCAR's Cooperative Programs for the Advancement of Earth System Science
Climate Variability Predictability	NA23OAR4310297
Australian Government
Schmidt Sciences, LLC
LSU
ProOceans
US Department of Energy by Battelle Memorial Institute	DE-AC05-76RL01830
Quadrature Climate Foundation
Grantham Foundation for the Protection of the Environment
Indiana University Environmental Resilience Institute
European Union's Horizon 2020	101059877

Keywords

Ocean alkalinity enhancement
Solar-radiation management
Stratospheric aerosol injection
Microbial metabolic-rates
Carbon-dioxide removal
Earth system models
Global climate
Inorganic carbon
Organic-matter
Deep-sea

Access to Document

10.1029/2024RG000876

Cite this

Roberts, K. E., Rohr, T., Raven, M. R., Diamond, M. S., Visioni, D., Kravitz, B., Heneghan, R., Petrik, C. M., Bianchi, D., Ortega-Cisneros, K., Morrison, M. A., van Heerden, V., Wiseman, N. A., Anil, G., Cannizzo, Z. J., Coll, M., Coupe, J., Freedman, R., Krumhardt, K., ... Harrison, C. S. (2026). Potential Impacts of Climate Interventions on Marine Ecosystems. Reviews of Geophysics, 64(1), Article e2024RG000876. https://doi.org/10.1029/2024RG000876

@article{bd5536bda764494391dc3ca74a4dae30,

title = "Potential Impacts of Climate Interventions on Marine Ecosystems",

abstract = "Rising global temperatures pose significant risks to marine ecosystems, biodiversity, and fisheries. Recent comprehensive assessments suggest that large-scale mitigation efforts to limit warming are falling short, and all feasible future climate projections, including those that represent optimistic emissions reductions, exceed the Paris Agreement's 1.5°C or 2° warming targets during this century. While avoiding further CO2 emissions remains the most effective way to prevent environmental destabilization, interest is growing in climate interventions—deliberate, large-scale manipulations of the environment aimed at reducing global warming. These include carbon dioxide removal (CDR) to reduce atmospheric CO2 concentrations over time, and solar radiation modification (SRM), which reflects sunlight to lower surface temperatures but does not address root CO2 causes. The effects of these interventions on marine ecosystems, both direct and in combination with ongoing climate change, remain highly uncertain. Given the ocean's central role in regulating Earth's climate and supporting global food security, understanding these potential effects is crucial. This review provides an overview of proposed intervention methodologies for marine CDR and SRM and outlines the potential trade-offs and knowledge gaps associated with their impacts on marine ecosystems. Climate interventions have the potential to reduce warming-driven impacts, but could also alter marine food systems, biodiversity and ecosystem function. Effects will vary by pathway, scale, and regional context. Pathway-specific impact assessments are thus crucial to quantify trade-offs between plausible intervention scenarios as well as to identify their expected impacts on marine ecosystems in order to prioritize scaling efforts for low-risk pathways and avoid high-risk scenarios.",

keywords = "Ocean alkalinity enhancement, Solar-radiation management, Stratospheric aerosol injection, Microbial metabolic-rates, Carbon-dioxide removal, Earth system models, Global climate, Inorganic carbon, Organic-matter, Deep-sea",

author = "Roberts, \{Kelsey E.\} and Tyler Rohr and Raven, \{Morgan R.\} and Diamond, \{Michael S.\} and Daniele Visioni and Ben Kravitz and Ryan Heneghan and Petrik, \{Colleen M.\} and Daniele Bianchi and Kelly Ortega-Cisneros and Morrison, \{Monica A.\} and \{van Heerden\}, Vanessa and Wiseman, \{Nicola A.\} and Gouri Anil and Cannizzo, \{Zachary J.\} and Marta Coll and Joshua Coupe and Ryan Freedman and Kristen Krumhardt and Lester Kwiatkowski and Lovenduski, \{Nicole S.\} and Luo, \{Jessica Y.\} and Olivarez, \{Holly C.\} and Alan Robock and Jeroen Steenbeek and Harrison, \{Cheryl S.\}",

note = "Publisher Copyright: {\textcopyright} 2026. The Author(s).",

year = "2026",

month = jan,

day = "14",

doi = "10.1029/2024RG000876",

language = "English",

volume = "64",

journal = "Reviews of Geophysics",

issn = "8755-1209",

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Roberts, KE, Rohr, T, Raven, MR, Diamond, MS, Visioni, D, Kravitz, B, Heneghan, R, Petrik, CM, Bianchi, D, Ortega-Cisneros, K, Morrison, MA, van Heerden, V, Wiseman, NA, Anil, G, Cannizzo, ZJ, Coll, M, Coupe, J, Freedman, R, Krumhardt, K, Kwiatkowski, L, Lovenduski, NS, Luo, JY, Olivarez, HC, Robock, A, Steenbeek, J & Harrison, CS 2026, 'Potential Impacts of Climate Interventions on Marine Ecosystems', Reviews of Geophysics, vol. 64, no. 1, e2024RG000876. https://doi.org/10.1029/2024RG000876

TY - JOUR

T1 - Potential Impacts of Climate Interventions on Marine Ecosystems

AU - Roberts, Kelsey E.

AU - Rohr, Tyler

AU - Raven, Morgan R.

AU - Diamond, Michael S.

AU - Visioni, Daniele

AU - Kravitz, Ben

AU - Heneghan, Ryan

AU - Petrik, Colleen M.

AU - Bianchi, Daniele

AU - Ortega-Cisneros, Kelly

AU - Morrison, Monica A.

AU - van Heerden, Vanessa

AU - Wiseman, Nicola A.

AU - Anil, Gouri

AU - Cannizzo, Zachary J.

AU - Coll, Marta

AU - Coupe, Joshua

AU - Freedman, Ryan

AU - Krumhardt, Kristen

AU - Kwiatkowski, Lester

AU - Lovenduski, Nicole S.

AU - Luo, Jessica Y.

AU - Olivarez, Holly C.

AU - Robock, Alan

AU - Steenbeek, Jeroen

AU - Harrison, Cheryl S.

PY - 2026/1/14

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N2 - Rising global temperatures pose significant risks to marine ecosystems, biodiversity, and fisheries. Recent comprehensive assessments suggest that large-scale mitigation efforts to limit warming are falling short, and all feasible future climate projections, including those that represent optimistic emissions reductions, exceed the Paris Agreement's 1.5°C or 2° warming targets during this century. While avoiding further CO2 emissions remains the most effective way to prevent environmental destabilization, interest is growing in climate interventions—deliberate, large-scale manipulations of the environment aimed at reducing global warming. These include carbon dioxide removal (CDR) to reduce atmospheric CO2 concentrations over time, and solar radiation modification (SRM), which reflects sunlight to lower surface temperatures but does not address root CO2 causes. The effects of these interventions on marine ecosystems, both direct and in combination with ongoing climate change, remain highly uncertain. Given the ocean's central role in regulating Earth's climate and supporting global food security, understanding these potential effects is crucial. This review provides an overview of proposed intervention methodologies for marine CDR and SRM and outlines the potential trade-offs and knowledge gaps associated with their impacts on marine ecosystems. Climate interventions have the potential to reduce warming-driven impacts, but could also alter marine food systems, biodiversity and ecosystem function. Effects will vary by pathway, scale, and regional context. Pathway-specific impact assessments are thus crucial to quantify trade-offs between plausible intervention scenarios as well as to identify their expected impacts on marine ecosystems in order to prioritize scaling efforts for low-risk pathways and avoid high-risk scenarios.

AB - Rising global temperatures pose significant risks to marine ecosystems, biodiversity, and fisheries. Recent comprehensive assessments suggest that large-scale mitigation efforts to limit warming are falling short, and all feasible future climate projections, including those that represent optimistic emissions reductions, exceed the Paris Agreement's 1.5°C or 2° warming targets during this century. While avoiding further CO2 emissions remains the most effective way to prevent environmental destabilization, interest is growing in climate interventions—deliberate, large-scale manipulations of the environment aimed at reducing global warming. These include carbon dioxide removal (CDR) to reduce atmospheric CO2 concentrations over time, and solar radiation modification (SRM), which reflects sunlight to lower surface temperatures but does not address root CO2 causes. The effects of these interventions on marine ecosystems, both direct and in combination with ongoing climate change, remain highly uncertain. Given the ocean's central role in regulating Earth's climate and supporting global food security, understanding these potential effects is crucial. This review provides an overview of proposed intervention methodologies for marine CDR and SRM and outlines the potential trade-offs and knowledge gaps associated with their impacts on marine ecosystems. Climate interventions have the potential to reduce warming-driven impacts, but could also alter marine food systems, biodiversity and ecosystem function. Effects will vary by pathway, scale, and regional context. Pathway-specific impact assessments are thus crucial to quantify trade-offs between plausible intervention scenarios as well as to identify their expected impacts on marine ecosystems in order to prioritize scaling efforts for low-risk pathways and avoid high-risk scenarios.

KW - Ocean alkalinity enhancement

KW - Solar-radiation management

KW - Stratospheric aerosol injection

KW - Microbial metabolic-rates

KW - Carbon-dioxide removal

KW - Earth system models

KW - Global climate

KW - Inorganic carbon

KW - Organic-matter

KW - Deep-sea

UR - https://www.scopus.com/pages/publications/105027392391

U2 - 10.1029/2024RG000876

DO - 10.1029/2024RG000876

M3 - Review article

AN - SCOPUS:105027392391

SN - 8755-1209

VL - 64

JO - Reviews of Geophysics

JF - Reviews of Geophysics

IS - 1

M1 - e2024RG000876

ER -

Potential Impacts of Climate Interventions on Marine Ecosystems

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