Abstract

AbstractQuantifying variability in the ocean carbon sink remains problematic due to sparse observations and spatiotemporal variability in surface ocean pCO2. To address this challenge, we have updated and improved ECCO‐Darwin, a global ocean biogeochemistry model that assimilates both physical and biogeochemical observations. The model consists of an adjoint‐based ocean circulation estimate from the Estimating the Circulation and Climate of the Ocean (ECCO) consortium and an ecosystem model developed by the Massachusetts Institute of Technology Darwin Project. In addition to the data‐constrained ECCO physics, a Green's function approach is used to optimize the biogeochemistry by adjusting initial conditions and six biogeochemical parameters. Over seasonal to multidecadal timescales (1995–2017), ECCO‐Darwin exhibits broad‐scale consistency with observed surface ocean pCO2 and air‐sea CO2 flux reconstructions in most biomes, particularly in the subtropical and equatorial regions. The largest differences between CO2 uptake occur in subpolar seasonally stratified biomes, where ECCO‐Darwin results in stronger winter uptake. Compared to the Global Carbon Project OBMs, ECCO‐Darwin has a time‐mean global ocean CO2 sink (2.47 ± 0.50 Pg C year−1) and interannual variability that are more consistent with interpolation‐based products. Compared to interpolation‐based methods, ECCO‐Darwin is less sensitive to sparse and irregularly sampled observations. Thus, ECCO‐Darwin provides a basis for identifying and predicting the consequences of natural and anthropogenic perturbations to the ocean carbon cycle, as well as the climate‐related sensitivity of marine ecosystems. Our study further highlights the importance of physically consistent, property‐conserving reconstructions, as are provided by ECCO, for ocean biogeochemistry studies.

Highlights

  • The ocean plays a vital role in regulating the global climate system and mitigating climate change

  • The ECCO‐Darwin OBM described in this paper is based on a global ocean and sea ice configuration of the Massachusetts Institute of Technology (MIT) general circulation model (MITgcm) (Marshall et al, 1997) and on the pilot study described in Brix et al (2015)

  • ED generally reproduces the time‐ mean large‐scale spatial patterns of elevated surface ocean pCO2 and outgassing in the equatorial regions and high‐latitude uptake shown in all interpolation‐based products (Figures 3 and 4)

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Summary

Introduction

The ocean plays a vital role in regulating the global climate system and mitigating climate change. Quantifying the magnitude and time‐space variability of the oceanic CO2 sink has been recognized as an important goal in the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (IPCC, 2013). Addressing this goal will improve predictions of the future climate trajectory, assist in the formulation of climate‐related policies, and help implement mitigation and adaptation strategies

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