date and time submitted | name | id & link | system costs [bnEUR/a] | marginal abatement cost [EUR/tCO2] | difference to default | downloads |
---|---|---|---|---|---|---|
2024-03-14 16:57:28 | EU with PV and wind IEA cost reduced 40% in solar 2050_45h sampling_transmission of 4GW | e6d6c67e-2d92-4419-bea4-5f29ab7d1ed4 | 556.62 | 261.35 | frequency: 193 -> 45; solar_cost: 302.0 -> 199.2; offwind_cost: 1416.0 -> 1137.6; onwind_cost: 963.0 -> 1266.0; linemax_extension: 10.0 -> 4.0; line_volume: 1.5 -> 2.0 | zip file of all results | PyPSA network file | config.yaml file |
All costs are in 2015 euros, EUR-2015.
starting grid | grid reinforcement and other investments | hydrogen network and electrolyser capacity
e6d6c67e-2d92-4419-bea4-5f29ab7d1ed4 | EU with PV and wind IEA cost reduced 40% in solar 2050_45h sampling_transmission of 4GW
Note that primary energy for wind, solar and hydroelectricity is accounted for using the direct equivalence method, i.e. assuming a 100% correspondence between primary energy and electricity generation.
Electricity includes electricity demand from electric vehicles, newly-electrified industry and heat pumps in individual buildings, but excludes electricity demand for water electrolysis. Hydrogen includes hydrogen demand for land transport, shipping, industry and ammonia production, but excludes hydrogen demand for synthesis into hydrocarbons. Liquid hydrocarbons include aviation fuel and feedstock for basic chemicals production (mostly for plastics).