Abstract We describe the ocean general circulation model ICON-O of the Max Planck Institute for Meteorology, which forms the ocean-sea ice component of the Earth system model ICON-ESM. ICON-O relies on innovative structure-preserving finite volume numerics. We demonstrate the fundamental ability of ICON-O to simulate key features of global ocean dynamics at both uniform and non-uniform resolution. Two experiments are analyzed and compared with observations, one with a nearly uniform and eddy-rich resolution of ?10?km and another with a telescoping configuration whose resolution varies smoothly from globally ?80?km to ?10?km in a focal region in the North Atlantic. Our results show first, that ICON-O on the nearly uniform grid simulates an o...
ICON-A is the new icosahedral nonhydrostatic (ICON) atmospheric general circulation model in a confi...
Unstructured-mesh models are common in coastal ocean modeling, but their applications are still at t...
Earth system models are fundamental to understanding and projecting climate change. The models have ...
This work documents ICON-ESM 1.0, the first version of a coupled model based 19 on the ICON framewor...
State-of-the-art Earth system models typically employ grid spacings of O(100 km), which is too coars...
State-of-the-art Earth System models typically employ grid spacings of O(100 km), too coarse to expl...
We evaluate the new icosahedral non-hydrostatic atmospheric (ICON-A) general circulation model of th...
We evaluate the new icosahedral nonhydrostatic atmospheric (ICON-A) general circulation model of the...
International audienceWe evaluate the new icosahedral nonhydrostatic atmospheric (ICON-A) general ci...
The global tide is simulated with the global ocean general circulation model ICON-O using a newly de...
ICON‐A is the new icosahedral non‐hydrostatic (ICON) atmospheric general circulation model in a conf...
Abstract The ICON framework has been considered for the use in global high-resolution, atmosphere-o...
Using the global and coupled ICOsahedral Nonhydrostatic model with the Sapphire configuration (ICON-...
How the upper-atmosphere branch of the circulation contributes to and interacts with the circulation...
ICON (ICOsahedral Nonhydrostatic) is a unified modeling system for global numerical weather predicti...
ICON-A is the new icosahedral nonhydrostatic (ICON) atmospheric general circulation model in a confi...
Unstructured-mesh models are common in coastal ocean modeling, but their applications are still at t...
Earth system models are fundamental to understanding and projecting climate change. The models have ...
This work documents ICON-ESM 1.0, the first version of a coupled model based 19 on the ICON framewor...
State-of-the-art Earth system models typically employ grid spacings of O(100 km), which is too coars...
State-of-the-art Earth System models typically employ grid spacings of O(100 km), too coarse to expl...
We evaluate the new icosahedral non-hydrostatic atmospheric (ICON-A) general circulation model of th...
We evaluate the new icosahedral nonhydrostatic atmospheric (ICON-A) general circulation model of the...
International audienceWe evaluate the new icosahedral nonhydrostatic atmospheric (ICON-A) general ci...
The global tide is simulated with the global ocean general circulation model ICON-O using a newly de...
ICON‐A is the new icosahedral non‐hydrostatic (ICON) atmospheric general circulation model in a conf...
Abstract The ICON framework has been considered for the use in global high-resolution, atmosphere-o...
Using the global and coupled ICOsahedral Nonhydrostatic model with the Sapphire configuration (ICON-...
How the upper-atmosphere branch of the circulation contributes to and interacts with the circulation...
ICON (ICOsahedral Nonhydrostatic) is a unified modeling system for global numerical weather predicti...
ICON-A is the new icosahedral nonhydrostatic (ICON) atmospheric general circulation model in a confi...
Unstructured-mesh models are common in coastal ocean modeling, but their applications are still at t...
Earth system models are fundamental to understanding and projecting climate change. The models have ...