Modelling the renewable transition: Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model

J. Solé; R. Samsó; E. García-Ladona; A. García-Olivares; J. Ballabrera-Poy; T. Madurell; A. Turiel; O. Osychenko; D. Álvarez; U. Bardi; M. Baumann; K. Buchmann; Capellán-Pérez; M. Černý; Carpintero; I. De Blas; C. De Castro; J. D. De Lathouwer; C. Duce; L. Eggler; J. M. Enríquez; S. Falsini; K. Feng; N. Ferreras; F. Frechoso; K. Hubacek; A. Jones; R. Kaclíková; C. Kerschner; C. Kimmich; L. F. Lobejón; P. L. Lomas; G. Martelloni; M. Mediavilla; L. J. Miguel; D. Natalini; J. Nieto; A. Nikolaev; G. Parrado; S. Papagianni; I. Perissi; C. Ploiner; L. Radulov; P. Rodrigo; L. Sun; M. Theofilidi

doi:10.1016/j.rser.2020.110105

Modelling the renewable transition: Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model

J. Solé^*, R. Samsó, E. García-Ladona, A. García-Olivares, J. Ballabrera-Poy, T. Madurell, A. Turiel, O. Osychenko, D. Álvarez, U. Bardi, M. Baumann, K. Buchmann, Capellán-Pérez, M. Černý, Carpintero, I. De Blas, C. De Castro, J. D. De Lathouwer, C. Duce, L. EgglerJ. M. Enríquez, S. Falsini, K. Feng, N. Ferreras, F. Frechoso, K. Hubacek, A. Jones, R. Kaclíková, C. Kerschner, C. Kimmich, L. F. Lobejón, P. L. Lomas, G. Martelloni, M. Mediavilla, L. J. Miguel, D. Natalini, J. Nieto, A. Nikolaev, G. Parrado, S. Papagianni, I. Perissi, C. Ploiner, L. Radulov, P. Rodrigo, L. Sun, M. Theofilidi

^*Corresponding author for this work

Publication: Scientific journal › Journal article › peer-review

Abstract

This paper reviews different approaches to modelling the energy transition towards a zero carbon economy. It identifies a number of limitations in current approaches such as a lack of consideration of out-of-equilibrium situations (like an energy transition) and non-linear feedbacks. To tackle those issues, the new open source integrated assessment model pymedeas is introduced, which allows the exploration of the design and planning of appropriate strategies and policies for decarbonizing the energy sector at World and EU level. The main novelty of the new open-source model is that it addresses the energy transition by considering biophysical limits, availability of raw materials, and climate change impacts. This paper showcases the model capabilities through several simulation experiments to explore alternative pathways for the renewable transition. In the selected scenarios of this work, future shortage of fossil fuels is found to be the most influential factor of the simulations system evolution. Changes in efficiency and climate change damages are also important determinants influencing model outcomes.

Original language	English
Article number	110105
Pages (from-to)	1-13
Number of pages	13
Journal	Renewable and Sustainable Energy Reviews
Volume	132
DOIs	https://doi.org/10.1016/j.rser.2020.110105 https://doi.org/10.1016/j.rser.2020.110105
Publication status	Published - Oct 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020 The Author(s)

Keywords

Biophysical constraints
Climate damage
Energy costs
Energy efficiency
GHG emissions
Raw materials

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Cite this

Solé, J., Samsó, R., García-Ladona, E., García-Olivares, A., Ballabrera-Poy, J., Madurell, T., Turiel, A., Osychenko, O., Álvarez, D., Bardi, U., Baumann, M., Buchmann, K., Capellán-Pérez, Černý, M., Carpintero, De Blas, I., De Castro, C., De Lathouwer, J. D., Duce, C., ... Theofilidi, M. (2020). Modelling the renewable transition: Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model. Renewable and Sustainable Energy Reviews, 132, 1-13. Article 110105. https://doi.org/10.1016/j.rser.2020.110105, https://doi.org/10.1016/j.rser.2020.110105

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title = "Modelling the renewable transition: Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model",

abstract = "This paper reviews different approaches to modelling the energy transition towards a zero carbon economy. It identifies a number of limitations in current approaches such as a lack of consideration of out-of-equilibrium situations (like an energy transition) and non-linear feedbacks. To tackle those issues, the new open source integrated assessment model pymedeas is introduced, which allows the exploration of the design and planning of appropriate strategies and policies for decarbonizing the energy sector at World and EU level. The main novelty of the new open-source model is that it addresses the energy transition by considering biophysical limits, availability of raw materials, and climate change impacts. This paper showcases the model capabilities through several simulation experiments to explore alternative pathways for the renewable transition. In the selected scenarios of this work, future shortage of fossil fuels is found to be the most influential factor of the simulations system evolution. Changes in efficiency and climate change damages are also important determinants influencing model outcomes.",

keywords = "Biophysical constraints, Climate damage, Energy costs, Energy efficiency, GHG emissions, Raw materials",

author = "J. Sol{\'e} and R. Sams{\'o} and E. Garc{\'i}a-Ladona and A. Garc{\'i}a-Olivares and J. Ballabrera-Poy and T. Madurell and A. Turiel and O. Osychenko and D. {\'A}lvarez and U. Bardi and M. Baumann and K. Buchmann and Capell{\'a}n-P{\'e}rez and M. {\v C}ern{\'y} and Carpintero and \{De Blas\}, I. and \{De Castro\}, C. and \{De Lathouwer\}, \{J. D.\} and C. Duce and L. Eggler and Enr{\'i}quez, \{J. M.\} and S. Falsini and K. Feng and N. Ferreras and F. Frechoso and K. Hubacek and A. Jones and R. Kacl{\'i}kov{\'a} and C. Kerschner and C. Kimmich and Lobej{\'o}n, \{L. F.\} and Lomas, \{P. L.\} and G. Martelloni and M. Mediavilla and Miguel, \{L. J.\} and D. Natalini and J. Nieto and A. Nikolaev and G. Parrado and S. Papagianni and I. Perissi and C. Ploiner and L. Radulov and P. Rodrigo and L. Sun and M. Theofilidi",

note = "Publisher Copyright: {\textcopyright} 2020 The Author(s)",

year = "2020",

month = oct,

doi = "10.1016/j.rser.2020.110105",

language = "English",

volume = "132",

pages = "1--13",

journal = "Renewable and Sustainable Energy Reviews",

issn = "1364-0321",

publisher = "Elsevier Ltd.",

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Solé, J, Samsó, R, García-Ladona, E, García-Olivares, A, Ballabrera-Poy, J, Madurell, T, Turiel, A, Osychenko, O, Álvarez, D, Bardi, U, Baumann, M, Buchmann, K, Capellán-Pérez, , Černý, M, Carpintero, De Blas, I, De Castro, C, De Lathouwer, JD, Duce, C, Eggler, L, Enríquez, JM, Falsini, S, Feng, K, Ferreras, N, Frechoso, F, Hubacek, K, Jones, A, Kaclíková, R, Kerschner, C, Kimmich, C, Lobejón, LF, Lomas, PL, Martelloni, G, Mediavilla, M, Miguel, LJ, Natalini, D, Nieto, J, Nikolaev, A, Parrado, G, Papagianni, S, Perissi, I, Ploiner, C, Radulov, L, Rodrigo, P, Sun, L & Theofilidi, M 2020, 'Modelling the renewable transition: Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model', Renewable and Sustainable Energy Reviews, vol. 132, 110105, pp. 1-13. https://doi.org/10.1016/j.rser.2020.110105, https://doi.org/10.1016/j.rser.2020.110105

TY - JOUR

T1 - Modelling the renewable transition

T2 - Scenarios and pathways for a decarbonized future using pymedeas, a new open-source energy systems model

AU - Solé, J.

AU - Samsó, R.

AU - García-Ladona, E.

AU - García-Olivares, A.

AU - Ballabrera-Poy, J.

AU - Madurell, T.

AU - Turiel, A.

AU - Osychenko, O.

AU - Álvarez, D.

AU - Bardi, U.

AU - Baumann, M.

AU - Buchmann, K.

AU - Capellán-Pérez,

AU - Černý, M.

AU - Carpintero,

AU - De Blas, I.

AU - De Castro, C.

AU - De Lathouwer, J. D.

AU - Duce, C.

AU - Eggler, L.

AU - Enríquez, J. M.

AU - Falsini, S.

AU - Feng, K.

AU - Ferreras, N.

AU - Frechoso, F.

AU - Hubacek, K.

AU - Jones, A.

AU - Kaclíková, R.

AU - Kerschner, C.

AU - Kimmich, C.

AU - Lobejón, L. F.

AU - Lomas, P. L.

AU - Martelloni, G.

AU - Mediavilla, M.

AU - Miguel, L. J.

AU - Natalini, D.

AU - Nieto, J.

AU - Nikolaev, A.

AU - Parrado, G.

AU - Papagianni, S.

AU - Perissi, I.

AU - Ploiner, C.

AU - Radulov, L.

AU - Rodrigo, P.

AU - Sun, L.

AU - Theofilidi, M.

PY - 2020/10

Y1 - 2020/10

N2 - This paper reviews different approaches to modelling the energy transition towards a zero carbon economy. It identifies a number of limitations in current approaches such as a lack of consideration of out-of-equilibrium situations (like an energy transition) and non-linear feedbacks. To tackle those issues, the new open source integrated assessment model pymedeas is introduced, which allows the exploration of the design and planning of appropriate strategies and policies for decarbonizing the energy sector at World and EU level. The main novelty of the new open-source model is that it addresses the energy transition by considering biophysical limits, availability of raw materials, and climate change impacts. This paper showcases the model capabilities through several simulation experiments to explore alternative pathways for the renewable transition. In the selected scenarios of this work, future shortage of fossil fuels is found to be the most influential factor of the simulations system evolution. Changes in efficiency and climate change damages are also important determinants influencing model outcomes.

AB - This paper reviews different approaches to modelling the energy transition towards a zero carbon economy. It identifies a number of limitations in current approaches such as a lack of consideration of out-of-equilibrium situations (like an energy transition) and non-linear feedbacks. To tackle those issues, the new open source integrated assessment model pymedeas is introduced, which allows the exploration of the design and planning of appropriate strategies and policies for decarbonizing the energy sector at World and EU level. The main novelty of the new open-source model is that it addresses the energy transition by considering biophysical limits, availability of raw materials, and climate change impacts. This paper showcases the model capabilities through several simulation experiments to explore alternative pathways for the renewable transition. In the selected scenarios of this work, future shortage of fossil fuels is found to be the most influential factor of the simulations system evolution. Changes in efficiency and climate change damages are also important determinants influencing model outcomes.

KW - Biophysical constraints

KW - Climate damage

KW - Energy costs

KW - Energy efficiency

KW - GHG emissions

KW - Raw materials

U2 - 10.1016/j.rser.2020.110105

DO - 10.1016/j.rser.2020.110105

M3 - Journal article

AN - SCOPUS:85088377694

SN - 1364-0321

VL - 132

SP - 1

EP - 13

JO - Renewable and Sustainable Energy Reviews

JF - Renewable and Sustainable Energy Reviews

M1 - 110105

ER -