BET: Difference between revisions
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{{ModelTemplate}} | {{ModelTemplate}} | ||
{{ModelInfoTemplate | {{ModelInfoTemplate | ||
|Name=BET | |Name=BET-GLUE | ||
|Version= | |Version=1.6-3.2 | ||
|ModelLink= | |ModelLink=https://doi.org/10.1007/s10584-020-02839-7 | ||
|participation=reference card only | |participation=reference card only | ||
|processState= | |processState=published | ||
}} | |||
{{InstitutionTemplate | |||
|abbr=CRIEPI | |||
|institution=Central Research Institute of Electric Power Industry | |||
|link=https://criepi.denken.or.jp/en/ | |||
|country=Japan | |||
}} | }} | ||
{{ScopeMethodTemplate | {{ScopeMethodTemplate | ||
|ModelTypeOption=Integrated assessment model | |ModelTypeOption=Integrated assessment model | ||
|GeographicalScopeOption=Global | |GeographicalScopeOption=Global | ||
|Objective=BET is a multi-regional, inter-temporal general equilibrium model with a detailed energy system and an aggregated representation of | |Objective=BET-GLUE comprises an energy-economic module (BET) and a bioenergy-land-use module (GLUE). | ||
BET is a multi-regional, inter-temporal general equilibrium model with a detailed energy system and an aggregated representation of macroeconomy that follows an optimal economic growth theory. The model explicitly handles energy service demand and end-use technologies in a global macroeconomic framework. This structure allows a systematic approach to examine trade-offs between advanced energy supply technologies and end-use efficiencies from a long-term global perspective across different mitigation policies and technologies. | |||
GLUE is a multi-regional, global land-use and energy model, which solves the system of land-use and biomass flow balance by recursive dynamics under a set of conditions including food and wood demand. Currently, GLUE is soft-linked with BET to provide biomass feedstock potentials. | |||
|SolutionConceptOption=General equilibrium (closed economy) | |SolutionConceptOption=General equilibrium (closed economy) | ||
|SolutionHorizonOption=Intertemporal optimization (foresight) | |SolutionHorizonOption=Intertemporal optimization (foresight) | ||
|SolutionMethodOption=Optimization | |SolutionMethodOption=Optimization | ||
|BaseYear=2010 | |BaseYear=2010 | ||
|TemporalText=The time domain internally has an extension of several decades beyond the horizon to avoid unexpected terminal effects. | |||
|TimeSteps=10 | |TimeSteps=10 | ||
|Horizon= | |Horizon=2150 | ||
|Nr=13 | |Nr=13 | ||
|Region=BRA (Brazil); CAZ (Canada, Australia, and New Zealand); CHA (China incl. Hng Kong); EUR (EU27+3 (Switzerland, Norway, and Iceland)); IND (India); JPN (Japan); MNA (Middle East and North Africa); OAS (Other Asia); OLA (Other Latin America); ORF (Other Reforming Economies); RUS (Russia); SSA (Sub-Saharan Africa); USA (United States) | |Region=BRA (Brazil); CAZ (Canada, Australia, and New Zealand); CHA (China incl. Hng Kong); EUR (EU27+3 (Switzerland, Norway, and Iceland)); IND (India); JPN (Japan); MNA (Middle East and North Africa); OAS (Other Asia); OLA (Other Latin America); ORF (Other Reforming Economies); RUS (Russia); SSA (Sub-Saharan Africa); USA (United States) | ||
|PoliciesOption=Emission tax; Emission pricing; Cap and trade | |||
|PoliciesOption=Emission tax; | |||
}} | }} | ||
{{Socio-economicTemplate | {{Socio-economicTemplate | ||
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}} | }} | ||
{{Macro-economyTemplate | {{Macro-economyTemplate | ||
|TradeOption=Coal; Oil; Gas; | |TradeOption=Coal; Oil; Gas; Emissions permits; Non-energy goods | ||
|CostMeasureOption=GDP loss; Consumption loss; Energy system cost mark-up | |CostMeasureOption=GDP loss; Consumption loss; Energy system cost mark-up | ||
|InstitutionalAndPoliticalFactorsOption=Technology costs differentiated by country/region | |InstitutionalAndPoliticalFactorsOption=Technology costs differentiated by country/region | ||
|CoalRUOption=Yes (supply curve) | |CoalRUOption=Yes (supply curve) | ||
|ConventionalOilRUOption=Yes (supply curve) | |ConventionalOilRUOption=Yes (supply curve) | ||
|UnconventionalOilRUOption=Yes (supply curve) | |||
|ConventionalGasRUOption=Yes (supply curve) | |ConventionalGasRUOption=Yes (supply curve) | ||
| | |UnconventionalGasRUOption=Yes (supply curve) | ||
|BioenergyRUOption=Yes (supply curve) | |BioenergyRUOption=Yes (supply curve) | ||
|IndustryESOption=Yes (physical) | |||
|IndustryESOption=Yes ( | |||
|EnergyESOption=Yes (physical & economic) | |EnergyESOption=Yes (physical & economic) | ||
|TransportationESOption=Yes ( | |TransportationESOption=Yes (physical) | ||
|ResidentialAndCommercialESOption=Yes ( | |ResidentialAndCommercialESOption=Yes (physical) | ||
|AgricultureESOption=Yes (physical) | |AgricultureESOption=Yes (physical) | ||
|ForestryESOption=Yes (physical) | |ForestryESOption=Yes (physical) | ||
|EnergyConversionTechnologyTCOption= | |EnergyConversionTechnologyTCOption=Exogenous technological change | ||
|EnergyEnd-useTCOption= | |EnergyEnd-useTCOption=Exogenous technological change | ||
|AgricultureTCOption=No technological change | |AgricultureTCOption=No technological change | ||
}} | }} | ||
{{EnergyTemplate | {{EnergyTemplate | ||
|EnergyTechnologyChoiceOption= | |EnergyTechnologyChoiceOption=Linear choice (lowest cost) | ||
|EnergyTechnologySubstitutabilityOption=Mostly high substitutability | |EnergyTechnologySubstitutabilityOption=Mostly high substitutability | ||
|EnergyTechnologyDeploymentOption=Expansion and decline constraints | |EnergyTechnologyDeploymentOption=Expansion and decline constraints | ||
|ElectricityTechnologyOption=Coal w/o CCS; Coal w/ CCS; Gas w/o CCS; Gas w/ CCS; Oil w/o CCS; Bioenergy w/o CCS; Bioenergy w/ CCS; Geothermal power; Nuclear power; Solar power | |ElectricityTechnologyOption=Coal w/o CCS; Coal w/ CCS; Gas w/o CCS; Gas w/ CCS; Oil w/o CCS; Bioenergy w/o CCS; Bioenergy w/ CCS; Geothermal power; Nuclear power; Solar power; Wind power; Wind power-onshore; Wind power-offshore; Hydroelectric power | ||
|HydrogenProductionOption=Coal to hydrogen w/ CCS; Electrolysis | |HydrogenProductionOption=Coal to hydrogen w/ CCS; Electrolysis | ||
|RefinedLiquidsOption=Coal to liquids w/o CCS; Bioliquids w/o CCS | |RefinedLiquidsOption=Coal to liquids w/o CCS; Bioliquids w/o CCS | ||
|RefinedGasesOption=Biomass to gas w/o CCS | |RefinedGasesOption=Biomass to gas w/o CCS | ||
|ElectricityGIOption=Yes (aggregate) | |ElectricityGIOption=Yes (aggregate) | ||
| | |GridInfrastructureText=Electricity grid infrastructure is crudely modeled, such as an upper limit of renewable energy | ||
|PassengerTransportationOption=Passenger trains; Light Duty Vehicles (LDVs); Electric LDVs; Gasoline LDVs; Passenger aircrafts | |PassengerTransportationOption=Passenger trains; Light Duty Vehicles (LDVs); Electric LDVs; Gasoline LDVs; Passenger aircrafts | ||
|PassengerTransportation=Fuel-cell LDVs | |PassengerTransportation=Fuel-cell LDVs | ||
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{{Land-useTemplate | {{Land-useTemplate | ||
|LandCoverOption=Cropland; Cropland food crops; Cropland feed crops; Cropland energy crops; Forest; Managed forest; Natural forest; Pasture | |LandCoverOption=Cropland; Cropland food crops; Cropland feed crops; Cropland energy crops; Forest; Managed forest; Natural forest; Pasture | ||
|LandCover=Other | |||
|AgricultureAndForestryDemandsOption=Agriculture food; Agriculture food crops; Agriculture food livestock; Agriculture feed; Agriculture feed crops; Agriculture feed livestock; Agriculture non-food; Agriculture non-food crops; Agriculture non-food livestock; Agriculture bioenergy; Agriculture residues; Forest industrial roundwood; Forest fuelwood; Forest residues | |AgricultureAndForestryDemandsOption=Agriculture food; Agriculture food crops; Agriculture food livestock; Agriculture feed; Agriculture feed crops; Agriculture feed livestock; Agriculture non-food; Agriculture non-food crops; Agriculture non-food livestock; Agriculture bioenergy; Agriculture residues; Forest industrial roundwood; Forest fuelwood; Forest residues | ||
| | |AgriculturalCommodities=Cereal; Other crops; Roots; Sugarcane; Meat | ||
}} | }} | ||
{{EmissionClimateTemplate | {{EmissionClimateTemplate | ||
|GHGOption=CO2 fossil fuels; CO2 land use | |GHGOption=CO2 fossil fuels; CO2 land use | ||
|GHG=CO2 industrial processes | |GHG=CO2 industrial processes | ||
|ClimateIndicatorOption=Concentration | |ClimateIndicatorOption=Concentration: CO2 | ||
|CarbonDioxideRemovalOption=Bioenergy with CCS; Direct air capture | |CarbonDioxideRemovalOption=Bioenergy with CCS; Direct air capture | ||
|CarbonDioxideRemovalText=Direct air capture is optional | |||
| | |||
}} | }} |
Latest revision as of 13:41, 3 September 2021
The reference card is a clearly defined description of model features. The numerous options have been organized into a limited amount of default and model specific (non default) options. In addition some features are described by a short clarifying text.
Legend:
- not implemented
- implemented
- implemented (not default option)
A page refresh may be needed after modifying data.
About
Name and version
BET-GLUE 1.6-3.2
Model link
Institution
Central Research Institute of Electric Power Industry (CRIEPI), Japan, https://criepi.denken.or.jp/en/.
Documentation
BET documentation is limited and consists of a reference card
Process state
published
Model scope and methods
Model type
- Integrated assessment model
- Energy system model
- CGE
- CBA-integrated assessment model
Geographical scope
- Global
- Regional
Objective
BET-GLUE comprises an energy-economic module (BET) and a bioenergy-land-use module (GLUE). BET is a multi-regional, inter-temporal general equilibrium model with a detailed energy system and an aggregated representation of macroeconomy that follows an optimal economic growth theory. The model explicitly handles energy service demand and end-use technologies in a global macroeconomic framework. This structure allows a systematic approach to examine trade-offs between advanced energy supply technologies and end-use efficiencies from a long-term global perspective across different mitigation policies and technologies. GLUE is a multi-regional, global land-use and energy model, which solves the system of land-use and biomass flow balance by recursive dynamics under a set of conditions including food and wood demand. Currently, GLUE is soft-linked with BET to provide biomass feedstock potentials.
Solution concept
- Partial equilibrium (price elastic demand)
- Partial equilibrium (fixed demand)
- General equilibrium (closed economy)
Solution horizon
- Recursive dynamic (myopic)
- Intertemporal optimization (foresight)
Solution method
- Simulation
- Optimization
Temporal dimension
Base year:2010, time steps:10, horizon: 2150
Spatial dimension
Number of regions:13
- BRA (Brazil)
- CAZ (Canada, Australia, and New Zealand)
- CHA (China incl. Hng Kong)
- EUR (EU27+3 (Switzerland, Norway, and Iceland))
- IND (India)
- JPN (Japan)
- MNA (Middle East and North Africa)
- OAS (Other Asia)
- OLA (Other Latin America)
- ORF (Other Reforming Economies)
- RUS (Russia)
- SSA (Sub-Saharan Africa)
- USA (United States)
Time discounting type
- Discount rate exogenous
- Discount rate endogenous
Policies
- Emission tax
- Emission pricing
- Cap and trade
- Fuel taxes
- Fuel subsidies
- Feed-in-tariff
- Portfolio standard
- Capacity targets
- Emission standards
- Energy efficiency standards
- Agricultural producer subsidies
- Agricultural consumer subsidies
- Land protection
- Pricing carbon stocks
Socio-economic drivers
Population
- Yes (exogenous)
- Yes (endogenous)
Population age structure
- Yes (exogenous)
- Yes (endogenous)
Education level
- Yes (exogenous)
- Yes (endogenous)
Urbanization rate
- Yes (exogenous)
- Yes (endogenous)
GDP
- Yes (exogenous)
- Yes (endogenous)
Income distribution
- Yes (exogenous)
- Yes (endogenous)
Employment rate
- Yes (exogenous)
- Yes (endogenous)
Labor productivity
- Yes (exogenous)
- Yes (endogenous)
Total factor productivity
- Yes (exogenous)
- Yes (endogenous)
Autonomous energy efficiency improvements
- Yes (exogenous)
- Yes (endogenous)
Macro-economy
Economic sector
Industry
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Energy
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Transportation
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Residential and commercial
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Agriculture
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Forestry
- Yes (physical)
- Yes (economic)
- Yes (physical & economic)
Macro-economy
Trade
- Coal
- Oil
- Gas
- Uranium
- Electricity
- Bioenergy crops
- Food crops
- Capital
- Emissions permits
- Non-energy goods
Cost measures
- GDP loss
- Welfare loss
- Consumption loss
- Area under MAC
- Energy system cost mark-up
Categorization by group
- Income
- Urban - rural
- Technology adoption
- Age
- Gender
- Education level
- Household size
Institutional and political factors
- Early retirement of capital allowed
- Interest rates differentiated by country/region
- Regional risk factors included
- Technology costs differentiated by country/region
- Technological change differentiated by country/region
- Behavioural change differentiated by country/region
- Constraints on cross country financial transfers
Resource use
Coal
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Conventional Oil
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Unconventional Oil
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Conventional Gas
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Unconventional Gas
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Uranium
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Bioenergy
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Water
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Raw Materials
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Land
- Yes (fixed)
- Yes (supply curve)
- Yes (process model)
Technological change
Energy conversion technologies
- No technological change
- Exogenous technological change
- Endogenous technological change
Energy End-use
- No technological change
- Exogenous technological change
- Endogenous technological change
Material Use
- No technological change
- Exogenous technological change
- Endogenous technological change
Agriculture (tc)
- No technological change
- Exogenous technological change
- Endogenous technological change
Energy
Energy technology substitution
Energy technology choice
- No discrete technology choices
- Logit choice model
- Production function
- Linear choice (lowest cost)
- Lowest cost with adjustment penalties
Energy technology substitutability
- Mostly high substitutability
- Mostly low substitutability
- Mixed high and low substitutability
Energy technology deployment
- Expansion and decline constraints
- System integration constraints
Energy
Electricity technologies
- Coal w/o CCS
- Coal w/ CCS
- Gas w/o CCS
- Gas w/ CCS
- Oil w/o CCS
- Oil w/ CCS
- Bioenergy w/o CCS
- Bioenergy w/ CCS
- Geothermal power
- Nuclear power
- Solar power
- Solar power-central PV
- Solar power-distributed PV
- Solar power-CSP
- Wind power
- Wind power-onshore
- Wind power-offshore
- Hydroelectric power
- Ocean power
Hydrogen production
- Coal to hydrogen w/o CCS
- Coal to hydrogen w/ CCS
- Natural gas to hydrogen w/o CCS
- Natural gas to hydrogen w/ CCS
- Oil to hydrogen w/o CCS
- Oil to hydrogen w/ CCS
- Biomass to hydrogen w/o CCS
- Biomass to hydrogen w/ CCS
- Nuclear thermochemical hydrogen
- Solar thermochemical hydrogen
- Electrolysis
Refined liquids
- Coal to liquids w/o CCS
- Coal to liquids w/ CCS
- Gas to liquids w/o CCS
- Gas to liquids w/ CCS
- Bioliquids w/o CCS
- Bioliquids w/ CCS
- Oil refining
Refined gases
- Coal to gas w/o CCS
- Coal to gas w/ CCS
- Oil to gas w/o CCS
- Oil to gas w/ CCS
- Biomass to gas w/o CCS
- Biomass to gas w/ CCS
Heat generation
- Coal heat
- Natural gas heat
- Oil heat
- Biomass heat
- Geothermal heat
- Solarthermal heat
- CHP (coupled heat and power)
Grid Infra Structure
Electricity
- Yes (aggregate)
- Yes (spatially explicit)
Gas
- Yes (aggregate)
- Yes (spatially explicit)
Heat
- Yes (aggregate)
- Yes (spatially explicit)
CO2
- Yes (aggregate)
- Yes (spatially explicit)
Hydrogen
- Yes (aggregate)
- Yes (spatially explicit)
Other grid and infrastructure
Note: Electricity grid infrastructure is crudely modeled, such as an upper limit of renewable energy
Energy end-use technologies
Passenger transportation
- Passenger trains
- Buses
- Light Duty Vehicles (LDVs)
- Electric LDVs
- Hydrogen LDVs
- Hybrid LDVs
- Gasoline LDVs
- Diesel LDVs
- Passenger aircrafts
- Fuel-cell LDVs
Note: Passengers and freights are not explicitly distinguished for trains, aircraft, and ship
Freight transportation
- Freight trains
- Heavy duty vehicles
- Freight aircrafts
- Freight ships
- Gasoline HDVs
- Hybrid HDVs
- Fuel-cell HDVs
Note: Passengers and freights are not explicitly distinguished for trains, aircraft, and ship
Industry
- Steel production
- Aluminium production
- Cement production
- Petrochemical production
- Paper production
- Plastics production
- Pulp production
- High temperature process
- Low temperature process
- Other electricity use
- Other solid fuel use
- Other liquid fuel use
- Other gas fuel use
Residential and commercial
- Space heating
- Space cooling
- Cooking
- Refrigeration
- Washing
- Lighting
- Water heating
- Other
Land-use
Land cover
- Cropland
- Cropland irrigated
- Cropland food crops
- Cropland feed crops
- Cropland energy crops
- Forest
- Managed forest
- Natural forest
- Pasture
- Shrubland
- Built-up area
- Other
Agriculture and forestry demands
- Agriculture food
- Agriculture food crops
- Agriculture food livestock
- Agriculture feed
- Agriculture feed crops
- Agriculture feed livestock
- Agriculture non-food
- Agriculture non-food crops
- Agriculture non-food livestock
- Agriculture bioenergy
- Agriculture residues
- Forest industrial roundwood
- Forest fuelwood
- Forest residues
Agricultural commodities
- Wheat
- Rice
- Other coarse grains
- Oilseeds
- Sugar crops
- Ruminant meat
- Non-ruminant meat and eggs
- Dairy products
- Cereal
- Other crops
- Roots
- Sugarcane
- Meat
Emission, climate and impacts
Greenhouse gases
- CO2 fossil fuels
- CO2 cement
- CO2 land use
- CH4 energy
- CH4 land use
- CH4 other
- N2O energy
- N2O land use
- N2O other
- CFCs
- HFCs
- SF6
- PFCs
- CO2 industrial processes
Pollutants
- CO energy
- CO land use
- CO other
- NOx energy
- NOx land use
- NOx other
- VOC energy
- VOC land use
- VOC other
- SO2 energy
- SO2 land use
- SO2 other
- BC energy
- BC land use
- BC other
- OC energy
- OC land use
- OC other
- NH3 energy
- NH3 land use
- NH3 other
Climate indicators
- Concentration: CO2
- Concentration: CH4
- Concentration: N2O
- Concentration: Kyoto gases
- Radiative forcing: CO2
- Radiative forcing: CH4
- Radiative forcing: N2O
- Radiative forcing: F-gases
- Radiative forcing: Kyoto gases
- Radiative forcing: aerosols
- Radiative forcing: land albedo
- Radiative forcing: AN3A
- Radiative forcing: total
- Temperature change
- Sea level rise
- Ocean acidification
Carbon dioxide removal
- Bioenergy with CCS
- Reforestation
- Afforestation
- Soil carbon enhancement
- Direct air capture
- Enhanced weathering
Note: Direct air capture is optional
Climate change impacts
- Agriculture
- Energy supply
- Energy demand
- Economic output
- Built capital
- Inequality
Co-Linkages
- Energy security: Fossil fuel imports & exports (region)
- Energy access: Household energy consumption
- Air pollution & health: Source-based aerosol emissions
- Air pollution & health: Health impacts of air Pollution
- Food access
- Water availability
- Biodiversity
Note: The time domain internally has an extension of several decades beyond the horizon to avoid unexpected terminal effects.