Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module
Аутори
Eggler, L.Capellan-Perez, I.
De Blas, I.
Alvarez Antelo, D.
Adam, A.
Papagianni, G.
Parrado-Hernando, Gonzalo
Herc, Luka
Pulido-Sanchez, D.
De Castro, C.
Frechoso, F.
Cazcarro, I.
Arto, I.
Samso, R.
Duić, Neven
Batas Bjelić, Ilija
Pfeifer, Antun
Конференцијски прилог (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
WILIAM (Within Limit Integrated Assessment Model) is a global multiregional IAM that combines economic, social, demographic, environmental, energy and material related aspects into one system dynamics model. It aims to provide stakeholders with an open source, welldocumented model to assess the feasibility, effectiveness, costs and impacts of different sustainability policy options. The adequate representation of energy production is key to assess future sustainability pathways. The main function of the developed energy module is to estimate the primary energy requirements and related GHG emissions for satisfying the economic demand. This goal was achieved by 7 major sub-modules: (1) End-use: translates the economic demand into final energy demand through a hybrid approach combining bottom-up with energy intensities for different sectors. (2) Energy transformation: maps the entire energy conversion chain from final to primary energy, including intermediary energy commodities and an all...ocation function for power plant utilization. (3) Energy capacity: keeps track of the current power plant capacity stock, decommissioning of expired capacities, as well as the build-up of new capacities. An allocation function for choosing the suitable technology types for new capacities stands at the core of this sub-module. (4) Computation of the EROI of green technologies (5) Variability and storage: keeps track of sub-annual time scale effects on annual energy balances depending on the current power system setup (DSM, Storage, sector coupling). (6) Consideration of techno-sustainable potentials of RES considering geographical, resource and Energy Return on Energy Investment (EROI) constraints. (7) Computation of the energy-related GHG emissions.
Кључне речи:
Within Limit Integrated Assessment Model / energy production / energy transitionИзвор:
Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia, 2023, 151-151Издавач:
- Zagreb : Faculty of Mechanical Engineering and Naval Architecture
Институција/група
Институт техничких наука САНУ / Institute of Technical Sciences of SASATY - CONF AU - Eggler, L. AU - Capellan-Perez, I. AU - De Blas, I. AU - Alvarez Antelo, D. AU - Adam, A. AU - Papagianni, G. AU - Parrado-Hernando, Gonzalo AU - Herc, Luka AU - Pulido-Sanchez, D. AU - De Castro, C. AU - Frechoso, F. AU - Cazcarro, I. AU - Arto, I. AU - Samso, R. AU - Duić, Neven AU - Batas Bjelić, Ilija AU - Pfeifer, Antun PY - 2023 UR - https://dais.sanu.ac.rs/123456789/16220 AB - WILIAM (Within Limit Integrated Assessment Model) is a global multiregional IAM that combines economic, social, demographic, environmental, energy and material related aspects into one system dynamics model. It aims to provide stakeholders with an open source, welldocumented model to assess the feasibility, effectiveness, costs and impacts of different sustainability policy options. The adequate representation of energy production is key to assess future sustainability pathways. The main function of the developed energy module is to estimate the primary energy requirements and related GHG emissions for satisfying the economic demand. This goal was achieved by 7 major sub-modules: (1) End-use: translates the economic demand into final energy demand through a hybrid approach combining bottom-up with energy intensities for different sectors. (2) Energy transformation: maps the entire energy conversion chain from final to primary energy, including intermediary energy commodities and an allocation function for power plant utilization. (3) Energy capacity: keeps track of the current power plant capacity stock, decommissioning of expired capacities, as well as the build-up of new capacities. An allocation function for choosing the suitable technology types for new capacities stands at the core of this sub-module. (4) Computation of the EROI of green technologies (5) Variability and storage: keeps track of sub-annual time scale effects on annual energy balances depending on the current power system setup (DSM, Storage, sector coupling). (6) Consideration of techno-sustainable potentials of RES considering geographical, resource and Energy Return on Energy Investment (EROI) constraints. (7) Computation of the energy-related GHG emissions. PB - Zagreb : Faculty of Mechanical Engineering and Naval Architecture C3 - Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia T1 - Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module SP - 151 EP - 151 UR - https://hdl.handle.net/21.15107/rcub_dais_16220 ER -
@conference{ author = "Eggler, L. and Capellan-Perez, I. and De Blas, I. and Alvarez Antelo, D. and Adam, A. and Papagianni, G. and Parrado-Hernando, Gonzalo and Herc, Luka and Pulido-Sanchez, D. and De Castro, C. and Frechoso, F. and Cazcarro, I. and Arto, I. and Samso, R. and Duić, Neven and Batas Bjelić, Ilija and Pfeifer, Antun", year = "2023", abstract = "WILIAM (Within Limit Integrated Assessment Model) is a global multiregional IAM that combines economic, social, demographic, environmental, energy and material related aspects into one system dynamics model. It aims to provide stakeholders with an open source, welldocumented model to assess the feasibility, effectiveness, costs and impacts of different sustainability policy options. The adequate representation of energy production is key to assess future sustainability pathways. The main function of the developed energy module is to estimate the primary energy requirements and related GHG emissions for satisfying the economic demand. This goal was achieved by 7 major sub-modules: (1) End-use: translates the economic demand into final energy demand through a hybrid approach combining bottom-up with energy intensities for different sectors. (2) Energy transformation: maps the entire energy conversion chain from final to primary energy, including intermediary energy commodities and an allocation function for power plant utilization. (3) Energy capacity: keeps track of the current power plant capacity stock, decommissioning of expired capacities, as well as the build-up of new capacities. An allocation function for choosing the suitable technology types for new capacities stands at the core of this sub-module. (4) Computation of the EROI of green technologies (5) Variability and storage: keeps track of sub-annual time scale effects on annual energy balances depending on the current power system setup (DSM, Storage, sector coupling). (6) Consideration of techno-sustainable potentials of RES considering geographical, resource and Energy Return on Energy Investment (EROI) constraints. (7) Computation of the energy-related GHG emissions.", publisher = "Zagreb : Faculty of Mechanical Engineering and Naval Architecture", journal = "Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia", title = "Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module", pages = "151-151", url = "https://hdl.handle.net/21.15107/rcub_dais_16220" }
Eggler, L., Capellan-Perez, I., De Blas, I., Alvarez Antelo, D., Adam, A., Papagianni, G., Parrado-Hernando, G., Herc, L., Pulido-Sanchez, D., De Castro, C., Frechoso, F., Cazcarro, I., Arto, I., Samso, R., Duić, N., Batas Bjelić, I.,& Pfeifer, A.. (2023). Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module. in Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia Zagreb : Faculty of Mechanical Engineering and Naval Architecture., 151-151. https://hdl.handle.net/21.15107/rcub_dais_16220
Eggler L, Capellan-Perez I, De Blas I, Alvarez Antelo D, Adam A, Papagianni G, Parrado-Hernando G, Herc L, Pulido-Sanchez D, De Castro C, Frechoso F, Cazcarro I, Arto I, Samso R, Duić N, Batas Bjelić I, Pfeifer A. Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module. in Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia. 2023;:151-151. https://hdl.handle.net/21.15107/rcub_dais_16220 .
Eggler, L., Capellan-Perez, I., De Blas, I., Alvarez Antelo, D., Adam, A., Papagianni, G., Parrado-Hernando, Gonzalo, Herc, Luka, Pulido-Sanchez, D., De Castro, C., Frechoso, F., Cazcarro, I., Arto, I., Samso, R., Duić, Neven, Batas Bjelić, Ilija, Pfeifer, Antun, "Modelling the long-term dynamics of the energy transition accounting for socioeconomic behaviour and biophysical constraints: overview of the Wiliam Energy Module" in Book of abstracts / 18th conference on sustainable development of energy, water and environment systems, September 24-29, 2023, Dubrovnik, Croatia (2023):151-151, https://hdl.handle.net/21.15107/rcub_dais_16220 .