Observation system simulation experiments in the Atlantic Ocean for enhanced surface ocean pCO2 reconstructions

To derive an optimal observation system for surface ocean pCO2 in the Atlantic Ocean and the Atlantic sector of the Southern Ocean, 11 observation system simulation experiments (OSSEs) were completed. Each OSSE is a feedforward neural network (FFNN) that is based on a different data distribution and...

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Bibliographic Details
Published in:Ocean Science
Main Authors: A. Denvil-Sommer, M. Gehlen, M. Vrac
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2021
Subjects:
envir
geo
Southern Ocean
Online Access:https://doi.org/10.5194/os-17-1011-2021
https://os.copernicus.org/articles/17/1011/2021/os-17-1011-2021.pdf
https://doaj.org/article/cba0020c1afb4d26ba216ebd34ffae19
Description
Summary:To derive an optimal observation system for surface ocean pCO2 in the Atlantic Ocean and the Atlantic sector of the Southern Ocean, 11 observation system simulation experiments (OSSEs) were completed. Each OSSE is a feedforward neural network (FFNN) that is based on a different data distribution and provides ocean surface pCO2 for the period 2008–2010 with a 5 d time interval. Based on the geographical and time positions from three observational platforms, volunteering observing ships, Argo floats and OceanSITES moorings, pseudo-observations were constructed using the outputs from an online-coupled physical–biogeochemical global ocean model with 0.25∘ nominal resolution. The aim of this work was to find an optimal spatial distribution of observations to supplement the widely used Surface Ocean CO2 Atlas (SOCAT) and to improve the accuracy of ocean surface pCO2 reconstructions. OSSEs showed that the additional data from mooring stations and an improved coverage of the Southern Hemisphere with biogeochemical ARGO floats corresponding to least 25 % of the density of active floats (2008–2010) (OSSE 10) would significantly improve the pCO2 reconstruction and reduce the bias of derived estimates of sea–air CO2 fluxes by 74 % compared to ocean model outputs.

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