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Energy efficiency potentials in the EU industry:impacts of deep decarbonization technologies
Increasing the energy efficiency in high energy demand sectors such as industry with a high reliance on coal, oil and natural gas is considered a pivotal step towards reducing greenhouse gas emissions and meeting the Paris Agreement targets. The European Commission published final energy demand projections for industry capturing current policies and market trends up to 2050. This Reference scenario for industry in 2050, however, does not give insights into the extent to which energy efficiency potentials are already implemented, in which sectors further efficiency can be achieved, to what extent or with which technologies. In this paper, the EU Reference scenario is broken down and compared to a Frozen Efficiency scenario with similar GDP developments but without energy efficiency. Through bottom-up analyses, it is found that with energy efficiency technologies alone, this Reference scenario for industry energy demands (10.6 EJ in 2050) cannot be achieved. That means that the EU Reference assumes higher energy efficiency than possible and too high an effect of current policies. In the Frozen Efficiency scenario, the energy demand reaches 14.2 EJ in 2050 due to the GDP development; 22% higher than 2015. Energy efficiency improvements and increased recycling can decrease industrial energy demand by 23% (11.3 EJ in 2050). In order to further reduce the energy demand, our analyses shows that the wide implementation of innovative in combination with electrification or hydrogen technologies can further decrease the 2050 energy demand to 9.7 EJ or 10.3 EJ, respectively.
Energy efficiency potentials in the EU industry:impacts of deep decarbonization technologies
Increasing the energy efficiency in high energy demand sectors such as industry with a high reliance on coal, oil and natural gas is considered a pivotal step towards reducing greenhouse gas emissions and meeting the Paris Agreement targets. The European Commission published final energy demand projections for industry capturing current policies and market trends up to 2050. This Reference scenario for industry in 2050, however, does not give insights into the extent to which energy efficiency potentials are already implemented, in which sectors further efficiency can be achieved, to what extent or with which technologies. In this paper, the EU Reference scenario is broken down and compared to a Frozen Efficiency scenario with similar GDP developments but without energy efficiency. Through bottom-up analyses, it is found that with energy efficiency technologies alone, this Reference scenario for industry energy demands (10.6 EJ in 2050) cannot be achieved. That means that the EU Reference assumes higher energy efficiency than possible and too high an effect of current policies. In the Frozen Efficiency scenario, the energy demand reaches 14.2 EJ in 2050 due to the GDP development; 22% higher than 2015. Energy efficiency improvements and increased recycling can decrease industrial energy demand by 23% (11.3 EJ in 2050). In order to further reduce the energy demand, our analyses shows that the wide implementation of innovative in combination with electrification or hydrogen technologies can further decrease the 2050 energy demand to 9.7 EJ or 10.3 EJ, respectively.
Energy efficiency potentials in the EU industry:impacts of deep decarbonization technologies
Kermeli, Katerina (Autor:in) / Crijns-Graus, Wina (Autor:in) / Johannsen, Rasmus Magni (Autor:in) / Mathiesen, Brian Vad (Autor:in)
01.12.2022
Kermeli , K , Crijns-Graus , W , Johannsen , R M & Mathiesen , B V 2022 , ' Energy efficiency potentials in the EU industry : impacts of deep decarbonization technologies ' , Energy Efficiency , vol. 15 , no. 8 , 68 . https://doi.org/10.1007/s12053-022-10071-8
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Decarbonization , /dk/atira/pure/sustainabledevelopmentgoals/affordable_and_clean_energy , Energy efficiency , Industry , Scenario analysis , Hydrogen technologies , Innovation , name=SDG 7 - Affordable and Clean Energy , /dk/atira/pure/sustainabledevelopmentgoals/industry_innovation_and_infrastructure , and Infrastructure , name=SDG 9 - Industry , Electrification
DDC:
690
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