Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9

We describe and test a new model of biological marine silicate cycling, implemented in the Kiel Marine Biogeochemical Model version 3 (KMBM3), embedded in the University of Victoria Earth System Climate Model (UVic ESCM) version 2.9. This new model adds diatoms, which are a key component of the biol...

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Published in:Geoscientific Model Development
Main Authors: Kvale, Karin F., Keller, David P., Koeve, Wolfgang, Meissner, Katrin J., Somes, Christopher J., Yao, Wanxuan, Oschlies, Andreas
Format: Article in Journal/Newspaper
Language:unknown
Published: Copernicus Publications (EGU) 2021
Subjects:
Antarctic
Southern Ocean
Antarc*
Online Access:http://oceanrep.geomar.de/50522/
http://oceanrep.geomar.de/50522/7/gmd-14-7255-2021.pdf
https://doi.org/10.5194/gmd-14-7255-2021
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institution Open Polar
collection OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel)
op_collection_id ftoceanrep
language unknown
description We describe and test a new model of biological marine silicate cycling, implemented in the Kiel Marine Biogeochemical Model version 3 (KMBM3), embedded in the University of Victoria Earth System Climate Model (UVic ESCM) version 2.9. This new model adds diatoms, which are a key component of the biological carbon pump, to an existing ecosystem model. This new model combines previously published parameterizations of a diatom functional type, opal production and export with a novel, temperature-dependent dissolution scheme. Modelled steady-state biogeochemical rates, carbon and nutrient distributions are similar to those found in previous model versions. The new model performs well against independent ocean biogeochemical indicators and captures the large-scale features of the marine silica cycle to a degree comparable to similar Earth system models. Furthermore, it is computationally efficient, allowing both fully coupled, long-timescale transient simulations and “offline” transport matrix spinups. We assess the fully coupled model against modern ocean observations, the historical record starting from 1960 and a business-as-usual atmospheric CO2 forcing to the year 2300. The model simulates a global decline in net primary production (NPP) of 1.4 % having occurred since the 1960s, with the strongest declines in the tropics, northern midlatitudes and Southern Ocean. The simulated global decline in NPP reverses after the year 2100 (forced by the extended RCP8.5 CO2 concentration scenario), and NPP returns to 98 % of the pre-industrial rate by 2300. This recovery is dominated by increasing primary production in the Southern Ocean, mostly by calcifying phytoplankton. Large increases in calcifying phytoplankton in the Southern Ocean offset a decline in the low latitudes, producing a global net calcite export in 2300 that varies only slightly from pre-industrial rates. Diatom distribution moves southward in our simulations, following the receding Antarctic ice front, but diatoms are outcompeted by calcifiers across most of their pre-industrial Southern Ocean habitat. Global opal export production thus drops to 75 % of its pre-industrial value by 2300. Model nutrients such as phosphate, silicate and nitrate build up along the Southern Ocean particle export pathway, but dissolved iron (for which ocean sources are held constant) increases in the upper ocean. This different behaviour of iron is attributed to a reduction of low-latitude NPP (and consequently, a reduction in both uptake and export and particle, including calcite scavenging), an increase in seawater temperatures (raising the solubility of particulate iron) and stratification that “traps” the iron near the surface. These results are meant to serve as a baseline for sensitivity assessments to be undertaken with this model in the future.
format Article in Journal/Newspaper
author Kvale, Karin F.
Keller, David P.
Koeve, Wolfgang
Meissner, Katrin J.
Somes, Christopher J.
Yao, Wanxuan
Oschlies, Andreas
spellingShingle Kvale, Karin F.
Keller, David P.
Koeve, Wolfgang
Meissner, Katrin J.
Somes, Christopher J.
Yao, Wanxuan
Oschlies, Andreas
Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
author_facet Kvale, Karin F.
Keller, David P.
Koeve, Wolfgang
Meissner, Katrin J.
Somes, Christopher J.
Yao, Wanxuan
Oschlies, Andreas
author_sort Kvale, Karin F.
title Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
title_short Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
title_full Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
title_fullStr Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
title_full_unstemmed Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9
title_sort explicit silicate cycling in the kiel marine biogeochemistry model, version 3 (kmbm3) embedded in the uvic escm version 2.9
publisher Copernicus Publications (EGU)
publishDate 2021
url http://oceanrep.geomar.de/50522/
http://oceanrep.geomar.de/50522/7/gmd-14-7255-2021.pdf
https://doi.org/10.5194/gmd-14-7255-2021
geographic Antarctic
Southern Ocean
geographic_facet Antarctic
Southern Ocean
genre Antarc*
Antarctic
Southern Ocean
genre_facet Antarc*
Antarctic
Southern Ocean
op_source Geoscientific Model Development, 14 . pp. 7255-7285.
op_relation http://oceanrep.geomar.de/50522/7/gmd-14-7255-2021.pdf
doi:10.5194/gmd-14-7255-2021
Kvale, K. F. , Keller, D. P. , Koeve, W. , Meissner, K. J., Somes, C. J. , Yao, W. and Oschlies, A. (2021) Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9. Open Access Geoscientific Model Development, 14 . pp. 7255-7285. DOI 10.5194/gmd-14-7255-2021 <http://dx.doi.org/10.5194/gmd-14-7255-2021>.
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5194/gmd-14-7255-2021
container_title Geoscientific Model Development
container_volume 14
container_issue 12
container_start_page 7255
op_container_end_page 7285
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spelling ftoceanrep:oai:oceanrep.geomar.de:50522 2023-05-15T14:00:49+02:00 Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9 Kvale, Karin F. Keller, David P. Koeve, Wolfgang Meissner, Katrin J. Somes, Christopher J. Yao, Wanxuan Oschlies, Andreas 2021-11-30 text http://oceanrep.geomar.de/50522/ http://oceanrep.geomar.de/50522/7/gmd-14-7255-2021.pdf https://doi.org/10.5194/gmd-14-7255-2021 unknown Copernicus Publications (EGU) http://oceanrep.geomar.de/50522/7/gmd-14-7255-2021.pdf doi:10.5194/gmd-14-7255-2021 Kvale, K. F. , Keller, D. P. , Koeve, W. , Meissner, K. J., Somes, C. J. , Yao, W. and Oschlies, A. (2021) Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9. Open Access Geoscientific Model Development, 14 . pp. 7255-7285. DOI 10.5194/gmd-14-7255-2021 <http://dx.doi.org/10.5194/gmd-14-7255-2021>. info:eu-repo/semantics/openAccess Geoscientific Model Development, 14 . pp. 7255-7285. Article PeerReviewed 2021 ftoceanrep https://doi.org/10.5194/gmd-14-7255-2021 2021-12-20T00:08:35Z We describe and test a new model of biological marine silicate cycling, implemented in the Kiel Marine Biogeochemical Model version 3 (KMBM3), embedded in the University of Victoria Earth System Climate Model (UVic ESCM) version 2.9. This new model adds diatoms, which are a key component of the biological carbon pump, to an existing ecosystem model. This new model combines previously published parameterizations of a diatom functional type, opal production and export with a novel, temperature-dependent dissolution scheme. Modelled steady-state biogeochemical rates, carbon and nutrient distributions are similar to those found in previous model versions. The new model performs well against independent ocean biogeochemical indicators and captures the large-scale features of the marine silica cycle to a degree comparable to similar Earth system models. Furthermore, it is computationally efficient, allowing both fully coupled, long-timescale transient simulations and “offline” transport matrix spinups. We assess the fully coupled model against modern ocean observations, the historical record starting from 1960 and a business-as-usual atmospheric CO2 forcing to the year 2300. The model simulates a global decline in net primary production (NPP) of 1.4 % having occurred since the 1960s, with the strongest declines in the tropics, northern midlatitudes and Southern Ocean. The simulated global decline in NPP reverses after the year 2100 (forced by the extended RCP8.5 CO2 concentration scenario), and NPP returns to 98 % of the pre-industrial rate by 2300. This recovery is dominated by increasing primary production in the Southern Ocean, mostly by calcifying phytoplankton. Large increases in calcifying phytoplankton in the Southern Ocean offset a decline in the low latitudes, producing a global net calcite export in 2300 that varies only slightly from pre-industrial rates. Diatom distribution moves southward in our simulations, following the receding Antarctic ice front, but diatoms are outcompeted by calcifiers across most of their pre-industrial Southern Ocean habitat. Global opal export production thus drops to 75 % of its pre-industrial value by 2300. Model nutrients such as phosphate, silicate and nitrate build up along the Southern Ocean particle export pathway, but dissolved iron (for which ocean sources are held constant) increases in the upper ocean. This different behaviour of iron is attributed to a reduction of low-latitude NPP (and consequently, a reduction in both uptake and export and particle, including calcite scavenging), an increase in seawater temperatures (raising the solubility of particulate iron) and stratification that “traps” the iron near the surface. These results are meant to serve as a baseline for sensitivity assessments to be undertaken with this model in the future. Article in Journal/Newspaper Antarc* Antarctic Southern Ocean OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel) Antarctic Southern Ocean Geoscientific Model Development 14 12 7255 7285

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