Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models

Yohei Takano; Tatiana Ilyina; Jerry Tjiputra; Yassir A Eddebbar; Sarah Berthet; Laurent Bopp; Erik Buitenhuis; Momme Butenschön; James R. Christian; John P. Dunne; Matthias Gröger; Hakase Hayashida; Jenny Hieronymus; Torben Koenigk; John P. Krasting; Mathew C. Long; Tomas Lovato; Hideyuki Nakano; Julien Palmieri; Jörg Schwinger; Roland Séférian; Parvadha Suntharalingam; Hiroaki Tatebe; Hiroyuki Tsujino; Shogo Urakawa; Michio Watanabe; Andrew Yool

doi:10.3389/fmars.2023.1139917

Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models

Yohei Takano, Tatiana Ilyina, Jerry Tjiputra, Yassir A Eddebbar, Sarah Berthet, Laurent Bopp, Erik Buitenhuis, Momme Butenschön, James R. Christian, John P. Dunne, Matthias Gröger, Hakase Hayashida, Jenny Hieronymus, Torben Koenigk, John P. Krasting, Mathew C. Long, Tomas Lovato, Hideyuki Nakano, Julien Palmieri, Jörg SchwingerRoland Séférian, Parvadha Suntharalingam, Hiroaki Tatebe, Hiroyuki Tsujino, Shogo Urakawa, Michio Watanabe, Andrew Yool

Research output: Contribution to journal › Article › peer-review

Abstract

Ocean deoxygenation due to anthropogenic warming represents a major threat to marine ecosystems and fisheries. Challenges remain in simulating the modern observed changes in the dissolved oxygen (O₂). Here, we present an analysis of upper ocean (0-700m) deoxygenation in recent decades from a suite of the Coupled Model Intercomparison Project phase 6 (CMIP6) ocean biogeochemical simulations. The physics and biogeochemical simulations include both ocean-only (the Ocean Model Intercomparison Project Phase 1 and 2, OMIP1 and OMIP2) and coupled Earth system (CMIP6 Historical) configurations. We examine simulated changes in the O₂ inventory and ocean heat content (OHC) over the past 5 decades across models. The models simulate spatially divergent evolution of O₂ trends over the past 5 decades. The trend (multi-model mean and spread) for upper ocean global O₂ inventory for each of the MIP simulations over the past 5 decades is 0.03 ± 0.39×1014 [mol/decade] for OMIP1, −0.37 ± 0.15×10¹⁴ [mol/decade] for OMIP2, and −1.06 ± 0.68×10¹⁴ [mol/decade] for CMIP6 Historical, respectively. The trend in the upper ocean global O₂ inventory for the latest observations based on the World Ocean Database 2018 is −0.98×10¹⁴ [mol/decade], in line with the CMIP6 Historical multi-model mean, though this recent observations-based trend estimate is weaker than previously reported trends. A comparison across ocean-only simulations from OMIP1 and OMIP2 suggests that differences in atmospheric forcing such as surface wind explain the simulated divergence across configurations in O₂ inventory changes. Additionally, a comparison of coupled model simulations from the CMIP6 Historical configuration indicates that differences in background mean states due to differences in spin-up duration and equilibrium states result in substantial differences in the climate change response of O₂. Finally, we discuss gaps and uncertainties in both ocean biogeochemical simulations and observations and explore possible future coordinated ocean biogeochemistry simulations to fill in gaps and unravel the mechanisms controlling the O₂ changes.

Original language	English
Article number	1139917
Journal	Frontiers in Marine Science
Volume	10
DOIs	https://doi.org/10.3389/fmars.2023.1139917
Publication status	Published - 1 Jan 2023
Externally published	Yes

Keywords

model spin-up
model’s equilibrium states
ocean and coupled model simulations
ocean deoxygenation
ocean warming

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.3389/fmars.2023.1139917

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Takano, Y., Ilyina, T., Tjiputra, J., Eddebbar, YA., Berthet, S., Bopp, L., Buitenhuis, E., Butenschön, M., Christian, J. R., Dunne, J. P., Gröger, M., Hayashida, H., Hieronymus, J., Koenigk, T., Krasting, J. P., Long, M. C., Lovato, T., Nakano, H., Palmieri, J., ... Yool, A. (2023). Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models. Frontiers in Marine Science, 10, Article 1139917. https://doi.org/10.3389/fmars.2023.1139917

@article{f5745f0e156f430fbe9f7b14144ecad3,

title = "Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models",

abstract = "Ocean deoxygenation due to anthropogenic warming represents a major threat to marine ecosystems and fisheries. Challenges remain in simulating the modern observed changes in the dissolved oxygen (O2). Here, we present an analysis of upper ocean (0-700m) deoxygenation in recent decades from a suite of the Coupled Model Intercomparison Project phase 6 (CMIP6) ocean biogeochemical simulations. The physics and biogeochemical simulations include both ocean-only (the Ocean Model Intercomparison Project Phase 1 and 2, OMIP1 and OMIP2) and coupled Earth system (CMIP6 Historical) configurations. We examine simulated changes in the O2 inventory and ocean heat content (OHC) over the past 5 decades across models. The models simulate spatially divergent evolution of O2 trends over the past 5 decades. The trend (multi-model mean and spread) for upper ocean global O2 inventory for each of the MIP simulations over the past 5 decades is 0.03 ± 0.39×1014 [mol/decade] for OMIP1, −0.37 ± 0.15×1014 [mol/decade] for OMIP2, and −1.06 ± 0.68×1014 [mol/decade] for CMIP6 Historical, respectively. The trend in the upper ocean global O2 inventory for the latest observations based on the World Ocean Database 2018 is −0.98×1014 [mol/decade], in line with the CMIP6 Historical multi-model mean, though this recent observations-based trend estimate is weaker than previously reported trends. A comparison across ocean-only simulations from OMIP1 and OMIP2 suggests that differences in atmospheric forcing such as surface wind explain the simulated divergence across configurations in O2 inventory changes. Additionally, a comparison of coupled model simulations from the CMIP6 Historical configuration indicates that differences in background mean states due to differences in spin-up duration and equilibrium states result in substantial differences in the climate change response of O2. Finally, we discuss gaps and uncertainties in both ocean biogeochemical simulations and observations and explore possible future coordinated ocean biogeochemistry simulations to fill in gaps and unravel the mechanisms controlling the O2 changes.",

keywords = "model spin-up, model{\textquoteright}s equilibrium states, ocean and coupled model simulations, ocean deoxygenation, ocean warming",

author = "Yohei Takano and Tatiana Ilyina and Jerry Tjiputra and Yassir A Eddebbar and Sarah Berthet and Laurent Bopp and Erik Buitenhuis and Momme Butensch{\"o}n and Christian, \{James R.\} and Dunne, \{John P.\} and Matthias Gr{\"o}ger and Hakase Hayashida and Jenny Hieronymus and Torben Koenigk and Krasting, \{John P.\} and Long, \{Mathew C.\} and Tomas Lovato and Hideyuki Nakano and Julien Palmieri and J{\"o}rg Schwinger and Roland S{\'e}f{\'e}rian and Parvadha Suntharalingam and Hiroaki Tatebe and Hiroyuki Tsujino and Shogo Urakawa and Michio Watanabe and Andrew Yool",

note = "Publisher Copyright: Copyright {\textcopyright} 2023 Takano, Ilyina, Tjiputra, Eddebbar, Berthet, Bopp, Buitenhuis, Butensch{\"o}n, Christian, Dunne, Gr{\"o}ger, Hayashida, Hieronymus, Koenigk, Krasting, Long, Lovato, Nakano, Palmieri, Schwinger, S{\'e}f{\'e}rian, Suntharalingam, Tatebe, Tsujino, Urakawa, Watanabe and Yool.",

year = "2023",

month = jan,

day = "1",

doi = "10.3389/fmars.2023.1139917",

language = "English",

volume = "10",

journal = "Frontiers in Marine Science",

issn = "2296-7745",

}

Takano, Y, Ilyina, T, Tjiputra, J, Eddebbar, YA, Berthet, S, Bopp, L, Buitenhuis, E, Butenschön, M, Christian, JR, Dunne, JP, Gröger, M, Hayashida, H, Hieronymus, J, Koenigk, T, Krasting, JP, Long, MC, Lovato, T, Nakano, H, Palmieri, J, Schwinger, J, Séférian, R, Suntharalingam, P, Tatebe, H, Tsujino, H, Urakawa, S, Watanabe, M & Yool, A 2023, 'Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models', Frontiers in Marine Science, vol. 10, 1139917. https://doi.org/10.3389/fmars.2023.1139917

TY - JOUR

T1 - Simulations of ocean deoxygenation in the historical era

T2 - insights from forced and coupled models

AU - Takano, Yohei

AU - Ilyina, Tatiana

AU - Tjiputra, Jerry

AU - Eddebbar, Yassir A

AU - Berthet, Sarah

AU - Bopp, Laurent

AU - Buitenhuis, Erik

AU - Butenschön, Momme

AU - Christian, James R.

AU - Dunne, John P.

AU - Gröger, Matthias

AU - Hayashida, Hakase

AU - Hieronymus, Jenny

AU - Koenigk, Torben

AU - Krasting, John P.

AU - Long, Mathew C.

AU - Lovato, Tomas

AU - Nakano, Hideyuki

AU - Palmieri, Julien

AU - Schwinger, Jörg

AU - Séférian, Roland

AU - Suntharalingam, Parvadha

AU - Tatebe, Hiroaki

AU - Tsujino, Hiroyuki

AU - Urakawa, Shogo

AU - Watanabe, Michio

AU - Yool, Andrew

N1 - Publisher Copyright: Copyright © 2023 Takano, Ilyina, Tjiputra, Eddebbar, Berthet, Bopp, Buitenhuis, Butenschön, Christian, Dunne, Gröger, Hayashida, Hieronymus, Koenigk, Krasting, Long, Lovato, Nakano, Palmieri, Schwinger, Séférian, Suntharalingam, Tatebe, Tsujino, Urakawa, Watanabe and Yool.

PY - 2023/1/1

Y1 - 2023/1/1

N2 - Ocean deoxygenation due to anthropogenic warming represents a major threat to marine ecosystems and fisheries. Challenges remain in simulating the modern observed changes in the dissolved oxygen (O2). Here, we present an analysis of upper ocean (0-700m) deoxygenation in recent decades from a suite of the Coupled Model Intercomparison Project phase 6 (CMIP6) ocean biogeochemical simulations. The physics and biogeochemical simulations include both ocean-only (the Ocean Model Intercomparison Project Phase 1 and 2, OMIP1 and OMIP2) and coupled Earth system (CMIP6 Historical) configurations. We examine simulated changes in the O2 inventory and ocean heat content (OHC) over the past 5 decades across models. The models simulate spatially divergent evolution of O2 trends over the past 5 decades. The trend (multi-model mean and spread) for upper ocean global O2 inventory for each of the MIP simulations over the past 5 decades is 0.03 ± 0.39×1014 [mol/decade] for OMIP1, −0.37 ± 0.15×1014 [mol/decade] for OMIP2, and −1.06 ± 0.68×1014 [mol/decade] for CMIP6 Historical, respectively. The trend in the upper ocean global O2 inventory for the latest observations based on the World Ocean Database 2018 is −0.98×1014 [mol/decade], in line with the CMIP6 Historical multi-model mean, though this recent observations-based trend estimate is weaker than previously reported trends. A comparison across ocean-only simulations from OMIP1 and OMIP2 suggests that differences in atmospheric forcing such as surface wind explain the simulated divergence across configurations in O2 inventory changes. Additionally, a comparison of coupled model simulations from the CMIP6 Historical configuration indicates that differences in background mean states due to differences in spin-up duration and equilibrium states result in substantial differences in the climate change response of O2. Finally, we discuss gaps and uncertainties in both ocean biogeochemical simulations and observations and explore possible future coordinated ocean biogeochemistry simulations to fill in gaps and unravel the mechanisms controlling the O2 changes.

AB - Ocean deoxygenation due to anthropogenic warming represents a major threat to marine ecosystems and fisheries. Challenges remain in simulating the modern observed changes in the dissolved oxygen (O2). Here, we present an analysis of upper ocean (0-700m) deoxygenation in recent decades from a suite of the Coupled Model Intercomparison Project phase 6 (CMIP6) ocean biogeochemical simulations. The physics and biogeochemical simulations include both ocean-only (the Ocean Model Intercomparison Project Phase 1 and 2, OMIP1 and OMIP2) and coupled Earth system (CMIP6 Historical) configurations. We examine simulated changes in the O2 inventory and ocean heat content (OHC) over the past 5 decades across models. The models simulate spatially divergent evolution of O2 trends over the past 5 decades. The trend (multi-model mean and spread) for upper ocean global O2 inventory for each of the MIP simulations over the past 5 decades is 0.03 ± 0.39×1014 [mol/decade] for OMIP1, −0.37 ± 0.15×1014 [mol/decade] for OMIP2, and −1.06 ± 0.68×1014 [mol/decade] for CMIP6 Historical, respectively. The trend in the upper ocean global O2 inventory for the latest observations based on the World Ocean Database 2018 is −0.98×1014 [mol/decade], in line with the CMIP6 Historical multi-model mean, though this recent observations-based trend estimate is weaker than previously reported trends. A comparison across ocean-only simulations from OMIP1 and OMIP2 suggests that differences in atmospheric forcing such as surface wind explain the simulated divergence across configurations in O2 inventory changes. Additionally, a comparison of coupled model simulations from the CMIP6 Historical configuration indicates that differences in background mean states due to differences in spin-up duration and equilibrium states result in substantial differences in the climate change response of O2. Finally, we discuss gaps and uncertainties in both ocean biogeochemical simulations and observations and explore possible future coordinated ocean biogeochemistry simulations to fill in gaps and unravel the mechanisms controlling the O2 changes.

KW - model spin-up

KW - model’s equilibrium states

KW - ocean and coupled model simulations

KW - ocean deoxygenation

KW - ocean warming

U2 - 10.3389/fmars.2023.1139917

DO - 10.3389/fmars.2023.1139917

M3 - Article

AN - SCOPUS:85177835727

SN - 2296-7745

VL - 10

JO - Frontiers in Marine Science

JF - Frontiers in Marine Science

M1 - 1139917

ER -

Simulations of ocean deoxygenation in the historical era: insights from forced and coupled models

Abstract

Keywords

UN SDGs

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