EERIE: Ocean Eddy-rich Kilometer-scale Climate Simulation with IFS-FESOM: SSP2-4.5 scenario run r1i1p1f1 day hfss gr v20240304

hdl:21.14102/30c13e25-79e4-30c0-91e4-3876723ec0e9

Ghosh, Rohit et al.

Dataset
EERIEhfsshighres-future-ssp245IFS-FESOM
Summary
[ Derived from parent entry - See data hierarchy tab ]

The EU project European Eddy RIch Earth System Models (EERIE) aims to advance kilometer-scale Earth System Models (ESMs) to reduce biases associated with low-resolution climate simulations. Its goal is to develop centennial-scale ESMs that explicitly resolve ocean mesoscale processes, thereby improving the representation of long-term climate evolution, variability, extremes, and potential tipping points.
One of these models, IFS-FESOM2-SR, couples the ECMWFs Integrated Forecast System (IFS) atmosphere (9 km resolution) with the FESOM2.5 ocean model (minimum 5 km resolution). The FESOM2.5 ocean model employs an NG5 unstructured triangular grid with 70 depth levels, achieving ~5 km resolution in eddy-rich mid- and high-latitudes and ~13 km in the tropics (Rackow et al., 2025). Its sea-ice component is FESIM (Danilov et al., 2015). The atmospheric model, IFS cycle 48r1 from ECMWF, uses a Tco1279 (~10 km) octahedral grid with 137 vertical levels. The setup follows Rackow et al. (2025) except for deep convection, where the operational IFS scheme is used instead of the modified reduced cloud-base mass flux version.
Following the HighResMIP protocol (Haarsma et al., 2016), the main simulations were preceded by a 50-year spin-up period using 1950 CMIP6 forcing. From the spin-up’s final state, two simulations were launched in parallel: a control run and a historical run using CMIP6 forcings. According to the HighResMIP protocol, the control simulation aimed to assess any potential drift within the simulation, enabling us to exclude the influence of such drift in order to better understand the impact of changes in radiative forcing over time.
After completion of the historical simulation, the experiment was extended along the SSP2-4.5 scenario pathway until 2050 to estimate near-future climate change using a long-term climate simulation at the kilometer scale. For this purpose, CMIP6 scenario forcings were used. Tropospheric aerosol estimates are based on the MACv2 aerosol forcing, which was subsequently adjusted to ensure compatibility with the CONFESS aerosol forcing used during the historical simulation.
Project
EERIE (European Eddy RIch Earth System Models)
Spatial Coverage
Longitude 0 to 360 Latitude -90 to 90
Temporal Coverage
2015-01-01 to 2050-12-31 (proleptic_gregorian)
Use constraints
Creative Commons Attribution Non Commercial Share Alike 4.0 International (https://creativecommons.org/licenses/by-nc-sa/4.0/)
Data Catalog
World Data Center for Climate
Access constraints
registered users
Size
40.88 GiB (43898810675 Byte)
Format
NetCDF
Status
in work
Creation Date
Future Review Date
2035-10-25
Download Permission
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Cite as
[ Derived from parent entry - See data hierarchy tab ]
Ghosh, Rohit; Cheedela, Suvarchal Kumar; Wickramage, Chathurika; Wachsmann, Fabian; Beyer, Sebastian; Aengenheyster, Matthias; Milinski, Sebastian; Koldunov, Nikolay; Sidorenko, Dmitry; Jung, Thomas (2025). EERIE: Ocean Eddy-rich Kilometer-scale Climate Simulation with Integrated Forecasting System (IFS) - Finite volumE Sea Ice-Ocean Model (FESOM2.5): SSP2-4.5 scenario run. World Data Center for Climate (WDCC) at DKRZ. https://www.wdc-climate.de/ui/entry?acronym=EERIE_FESOM_s245

BibTeX RIS
VariableAggregationUnit
surface_upward_sensible_heat_flux
CF
dayW m-2

Parent

EERIE: Ocean Eddy-rich Kilometer-scale Climate Simulation with Integrated Forecasting System (IFS) - Finite volumE Sea Ice-Ocean Model (FESOM2.5): SSP2-4.5 scenario run
Details

Parent project(s)

European Eddy RIch Earth System Models

[Entry acronym: EERIE_FESOM_s245_dayhfss] [Entry id: 5325962]