Implementing Riverine Biogeochemical Inputs in Ecco-Darwin: A Sensitivity Analysis of Terrestrial Fluxes in a Data-Assimilative Global Ocean Biogeochemistry Model

Authors

Raphaël Savelli, Moss Landing Marine Laboratories
Dustin Carroll, Moss Landing Marine LaboratoriesFollow
Dimitris Menemenlis, California Institute of Technology
Jonathan M. Lauderdale, Massachusetts Institute of Technology
Clément Bertin, California Institute of Technology
Stephanie Dutkiewicz, Massachusetts Institute of Technology
Manfredi Manizza, Scripps Institution of Oceanography
A. Anthony Bloom, California Institute of Technology
Karel Castro-Morales, Deutscher Wetterdienst
Charles E. Miller, California Institute of Technology
Marc Simard, California Institute of Technology
Kevin W. Bowman, California Institute of Technology
Hong Zhang, California Institute of Technology

Publication Date

1-26-2026

Document Type

Article

Publication Title

Geoscientific Model Development

Volume

19

Issue

2

DOI

10.5194/gmd-19-867-2026

First Page

867

Last Page

885

Abstract

Terrestrial sources of carbon and nutrients drive biogeochemical cycles in coastal regions and in the global ocean. Quantifying their impact on the spatiotemporal variability of the ocean carbon cycle is pivotal to understanding the distinctive characteristics of ocean basins dominated by riverine inflow. ECCO-Darwin is a data-constrained, global-ocean biogeochemistry model that has heretofore lacked lateral inputs of carbon and nutrients. The objective of this study is to add this new capability to ECCO-Darwin and to carry out a suite of sensitivity experiments in order to quantify the impact of these lateral fluxes on coastal- and open-ocean biogeochemistry. In this work, we use an optimized version of the data-assimilative global-ocean biogeochemistry ECCO-Darwin model to perform a sensitivity analysis of the ocean to lateral inputs of carbon and nutrients. We generate riverine inputs by combining daily point-source freshwater discharge from JRA55-do with the Global NEWS 2 watershed model, accounting for lateral inputs from 5171 watersheds worldwide. The addition of riverine inputs drives a small CO2 outgassing (+0.02 Pg C yr⁻¹) due to compensating processes at regional scales. In basins dominated by carbon runoff, such as the Tropical Atlantic and Arctic Oceans, the addition of riverine inputs increases CO2 outgassing (+13 % and +9 %, respectively). In contrast, runoff in nutrient-dominated Southeast Asia leads to increased CO2 uptake (+9 %). This new riverine biogeochemical input capability will enable future ECCO-Darwin solutions to better capture key processes that occur along coastal margins in global oceans.

Funding Number

80NSSC23K1232

Funding Sponsor

Ames Research Center

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 License.

Department

Moss Landing Marine Laboratories

Recommended Citation

Raphaël Savelli, Dustin Carroll, Dimitris Menemenlis, Jonathan M. Lauderdale, Clément Bertin, Stephanie Dutkiewicz, Manfredi Manizza, A. Anthony Bloom, Karel Castro-Morales, Charles E. Miller, Marc Simard, Kevin W. Bowman, and Hong Zhang. "Implementing Riverine Biogeochemical Inputs in Ecco-Darwin: A Sensitivity Analysis of Terrestrial Fluxes in a Data-Assimilative Global Ocean Biogeochemistry Model" Geoscientific Model Development (2026): 867-885. https://doi.org/10.5194/gmd-19-867-2026