Other end-use - IMAGE

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Model Documentation - IMAGE
Model scope and methods - IMAGE Model concept, solver and details - IMAGE Temporal dimension - IMAGE Spatial dimension - IMAGE Policy - IMAGE Socio-economic drivers - IMAGE Population - IMAGE Economic activity - IMAGE Macro-economy - IMAGE Production system and representation of economic sectors - IMAGE Energy - IMAGE Energy resource endowments - IMAGE Fossil energy resources - IMAGE Energy conversion - IMAGE Electricity - IMAGE Heat - IMAGE Gaseous fuels - IMAGE Grid, pipelines and other infrastructure - IMAGE Energy end-use - IMAGE Transport - IMAGE Residential and commercial sectors - IMAGE Industrial sector - IMAGE Other end-use - IMAGE Energy demand - IMAGE Technological change in energy - IMAGE Land-use - IMAGE Agriculture - IMAGE Forestry - IMAGE Bioenergy land-use - IMAGE Other land-use - IMAGE Emissions - IMAGE GHGs - IMAGE Climate - IMAGE Modelling of climate indicators - IMAGE Non-climate sustainability dimension - IMAGE References - IMAGE
Corresponding documentation
AIM-Hub BLUES C3IAM COFFEE-TEA DNE21+ GCAM GRACE IFs IMACLIM IMAGE POLES PROMETHEUS TIAM-UCL WITCH
Previous versions
Archive of IMAGE version 3.0
Model information
Model link	https://models.pbl.nl/image
Institution	PBL Netherlands Environmental Assessment Agency (PBL), Netherlands, https://www.pbl.nl/en.
Solution concept	Partial equilibrium (price elastic demand)
Solution method	Simulation
Anticipation	Simulation modelling framework, without foresight. However, a simplified version of the energy/climate part of the model (called FAIR) can be run prior to running the framework to obtain data for climate policy simulations.

CCS

For carbon capture and storage, three different steps are identified in the TIMER model: CO₂ capture and compression, CO₂ transport and CO₂ storage. Capture is assumed to be possible in electric power production, half of the industry sector and hydrogen production. Here, alternative technologies are defined that compete for market share with conventional technologies (without CCS). The former have higher costs and slightly lower conversion efficiencies and are therefore not chosen under default conditions; however, these technologies increase much less in price if a carbon price is introduced in the model. Capture is assumed to be at a maximum 95%; the remaining 5% is still influenced by the carbon price. The actual market shares of the conventional and CCS based technologies are determined in each market using multinomial logit equations. The capture costs are based on Hendriks et al. IMG_Hendriks_2002 IMG_Hendriks_2004a IMG_Hendriks_2004b. In the electric power sector, they increase generation costs by about 40-50% for natural gas and coal-based power plants. Expressed in terms of costs per unit of CO₂, this is equivalent to about 35-45$/tCO₂. Similar cost levels are assumed for industrial sources. CO₂ transport costs were estimated for each region and storage category on the basis of the distance between the main CO2 sources (industrial centres) and storage sites IMG_Hendriks_2004b. The estimated transport costs vary from 1-30 $/tCO₂ the majority being below 10$/tCO₂. Finally, for each region the potential for 11 storage categories has been estimated (in empty and still existing oil and gas fields, and on- and offshore thus a total of 8 combinations); enhanced coal-based methane recovery and aquifers (the original aquifer category was divided into two halves to allow more differentiation in costs). For each category, storage costs have been determined with typical values around 5-10$/tCO₂ IMG_Hendriks_2004b. The model uses these categories in the order of their transport and storage costs (the resource with lowest costs first).

Other end-use - IMAGE

CCS

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