SURFER v2.0: a flexible and simple model linking anthropogenic CO2 emissions 
and solar radiation modification to ocean acidification and sea level rise

Martínez-Montero, Marina; Crucifix, Michel; Couplet, Victor; Brede, Nuria; Botta, Nicola

doi:10.5194/gmd-15-8059-2022

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SURFER v2.0: a flexible and simple model linking anthropogenic CO2 emissions and solar radiation modification to ocean acidification and sea level rise

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Martínez-Montero, Marina
External Organizations;

Crucifix, Michel
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Couplet, Victor
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/persons/resource/Nuria.Brede

Brede, Nuria
Potsdam Institute for Climate Impact Research;

/persons/resource/nicola.botta

Botta, Nicola
Potsdam Institute for Climate Impact Research;

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Citation

Martínez-Montero, M., Crucifix, M., Couplet, V., Brede, N., Botta, N. (2022): SURFER v2.0: a flexible and simple model linking anthropogenic CO2 emissions and solar radiation modification to ocean acidification and sea level rise. - Geoscientific Model Development, 15, 21, 8059-8084.
https://doi.org/10.5194/gmd-15-8059-2022

Cite as: https://publications.pik-potsdam.de/pubman/item/item_27502

Abstract

We present SURFER, a novel reduced model for estimating the impact of CO2 emissions and solar radiation modification options on sea level rise and ocean acidification over timescales of several thousands of years. SURFER has been designed for the analysis of CO2 emission and solar radiation modification policies, for supporting the computation of optimal (CO2 emission and solar radiation modification) policies and for the study of commitment and responsibility under uncertainty. The model is based on a combination of conservation laws for the masses of atmospheric and oceanic carbon and for the oceanic temperature anomalies, and of ad-hoc parameterisations for the different sea level rise contributors: ice sheets, glaciers and ocean thermal expansion. It consists of 9 loosely coupled ordinary differential equations, is understandable, fast and easy to modify and calibrate. It reproduces the results of more sophisticated, high-dimensional earth system models on timescales up to millennia.