期刊
JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS
卷 126, 期 7, 页码 -出版社
AMER GEOPHYSICAL UNION
DOI: 10.1029/2021JC017235
关键词
Argentine Basin; model resolution; biogeochemistry; air-sea carbon flux; air-sea heat flux
类别
资金
- NSF's Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) Project under the NSF [PLR1425989]
- National Science Foundation, Division of Polar Programs (NSF) [PLR-1425989]
- International Argo Program
- NOAA programs
- CNES
Simulations of the Argentine Basin show that increasing model resolution from 1/3 degrees to 1/12 degrees enhances vertical transport and surface exchanges of heat, but has no significant effect on surface carbon fluxes despite enhancing downward transport of anomalous DIC.
Simulations of the Argentine Basin have large uncertainties associated with quantities such as air-sea exchanges of heat and carbon in current generation climate models and ocean reanalysis products. This is due to the complex topography, profound undersampling until recent years, and strong currents and mixing of subpolar and subtropical water masses in the basin. Because mixing of water masses is important here, model resolution is hypothesized to play an important role in estimating ocean quantities and determining overall budgets. We construct three regional ocean models with biogeochemistry at 1/3 degrees, 1/6 degrees, and 1/12 degrees resolutions for the year 2017 to investigate heat and carbon dynamics in the region and determine the effect of model resolution on these dynamics. Initial conditions and boundary forcing from BSOSE (the Biogeochemical Southern Ocean State Estimate (Verdy & Mazloff, 2017), ) and atmospheric forcing from ERA5 are used. The models are evaluated for accuracy by comparing output to Argo and BGC-Argo float profiles, BSOSE, and other reanalyses and mapped products. We then quantify the effect of resolution on model upper ocean heat and carbon transport and the associated air-sea exchanges. We determine that increasing the resolution from 1/3 degrees to 1/12 degrees enhances the upward vertical transport and surface exchanges of heat but causes no significant effect on surface carbon fluxes despite enhancing downward transport of anomalous DIC.
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