loading page

A first intercomparison of the simulated LGM carbon results within PMIP-carbon: role of the ocean boundary conditions
  • +13
  • Fanny Lhardy,
  • Nathaelle Bouttes,
  • Didier M. Roche,
  • Ayako Abe-Ouchi,
  • Zanna Chase,
  • Katherine A Crichton,
  • Ruza F Ivanovic,
  • Markus Jochum,
  • Masa Kageyama,
  • Hidetaka Kobayashi,
  • Laurie Menviel,
  • Juan Muglia,
  • Roman Nuterman,
  • Akira Oka,
  • Guido Vettoretti,
  • Akitomo Yamamoto
Fanny Lhardy
LSCE (Laboratoire des Sciences du Climat et de l'Environnement)

Corresponding Author:[email protected]

Author Profile
Nathaelle Bouttes
LSCE
Author Profile
Didier M. Roche
LSCE
Author Profile
Ayako Abe-Ouchi
University of Tokyo
Author Profile
Zanna Chase
University of Tasmania
Author Profile
Katherine A Crichton
University of Exeter
Author Profile
Ruza F Ivanovic
University of Leeds
Author Profile
Markus Jochum
University of Copenhagen
Author Profile
Masa Kageyama
Laboratoire des Sciences du Climat et de l'Environnement, France
Author Profile
Hidetaka Kobayashi
University of Tokyo
Author Profile
Laurie Menviel
University of New South Wales
Author Profile
Juan Muglia
Oregon State University
Author Profile
Roman Nuterman
Niels Bohr Institute, University of Copenhagen
Author Profile
Akira Oka
University of Tokyo
Author Profile
Guido Vettoretti
University of Copenhagen
Author Profile
Akitomo Yamamoto
Japan Agency for Marine-Earth and Technology
Author Profile

Abstract

Model intercomparison studies of coupled carbon-climate simulations have the potential to improve our understanding of the processes explaining the pCO2 drawdown at the Last Glacial Maximum (LGM) and to identify related model biases. Models participating in the Paleoclimate Modelling Intercomparison Project (PMIP) now frequently include the carbon cycle. The ongoing PMIP-carbon project provides the first opportunity to conduct multimodel comparisons of simulated carbon content for the LGM time window. However, such a study remains challenging due to differing implementation of ocean boundary conditions (e.g. bathymetry and coastlines reflecting the low sea level) and to various associated adjustments of biogeochemical variables (i.e. alkalinity, nutrients, dissolved inorganic carbon). After assessing the ocean volume of PMIP models at the pre-industrial and LGM, we investigate the impact of these modelling choices on the simulated carbon at the global scale, using both PMIP-carbon model outputs and sensitivity tests with the iLOVECLIM model. We show that the carbon distribution in reservoirs is significantly affected by the choice of ocean boundary conditions in iLOVECLIM. In particular, our simulations demonstrate a ~250 GtC effect of an alkalinity adjustment on carbon sequestration in the ocean. Finally, we observe that PMIP-carbon models with a freely evolving CO2 and no additional glacial mechanisms do not simulate the pCO2 drawdown at the LGM (with concentrations as high as 313, 331 and 315 ppm), especially if they use a low ocean volume. Our findings suggest that great care should be taken on accounting for large bathymetry changes in models including the carbon cycle.