CLIMBER-X

Earth System Model
 

CLIMBER-X is a comprehensive Earth System Model of Intermediate Complexity (EMIC), designed to simulate the evolution of the Earth system on time scales ranging from decades to glacial-interglacial cycles.
It is the successor of the first EMIC CLIMBER-2 developed at PIK.

What does the model do?

CLIMBER-X simulates the response of the Earth system to changes in different climate forcings, such as changes in greenhouse gas concentrations or in the Earth's orbital configuration. To do so the model represents the physical processes in atmosphere, ocean and on land that determine the climate state of the Earth. It also simulates the bio- and geochemical processes in the biosphere, soil, ocean and marine sediments and therefore allows for an interactive determination of the atmospheric CO2 and methane concentrations.
CLIMBER-X also includes a model for the continental ice sheets and a model for the response of the solid Earth to changes in surface load. Specifically, the model includes the following components:

  • SESAM: semi-empirical statistical-dynamical atmosphere model
  • GOLDSTEIN: 3-D frictional-geostrophic ocean model
  • HAMOCC: ocean and sediments carbon cycle model
  • SISIM: sea ice model
  • PALADYN: land model
  • SICOPOLIS: ice sheet model
  • VILMA: viscoelastic lithosphere and mantle model

Who maintains it?

CLIMBER-X is maintained and further developed by the working group Long-Term Dynamics of the Earth System of Research Domain 1 on PIK's own GitLab source code repository. The model is developed by Andrey Ganopolski, Matteo Willeit, Reinhard Calov and Stefanie Talento.

In what way is the model different from other models in the community?

CLIMBER-X differs from complex Earth system models mainly in that the atmosphere and ocean model components are based on approximations for the dynamics, instead of employing the Navier-Stokes equations as is in general circulation models. The advantage of this choice is that the model is much faster compared to Earth system models of a comparable spatial resolution.

Key publications

Model description paper(s) to be submitted soon to Geoscientific Model Development.