Deep decarbonisation pathways of the energy system in times of unprecedented uncertainty in the energy sector

Evangelos Panos; James Glynn; Socrates Kypreos; Antti Lehtilä; Xiufeng Yue; Brian Ó Gallachóir; David Daniels; Hancheng Dai

doi:10.1016/j.enpol.2023.113642

Deep decarbonisation pathways of the energy system in times of unprecedented uncertainty in the energy sector

Evangelos Panos^*, James Glynn^*, Socrates Kypreos, Antti Lehtilä, Xiufeng Yue, Brian Ó Gallachóir, David Daniels, Hancheng Dai

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

14 Citations (Scopus)

Abstract

Unprecedented investments in clean energy technology are required for a net-zero carbon energy system before temperatures breach the Paris Agreement goals. By performing a Monte-Carlo Analysis with the detailed ETSAP-TIAM Integrated Assessment Model and by generating 4000 scenarios of the world's energy system, climate and economy, we find that the uncertainty surrounding technology costs, resource potentials, climate sensitivity and the level of decoupling between energy demands and economic growth influence the efficiency of climate policies and accentuate investment risks in clean energy technologies. Contrary to other studies relying on exploring the uncertainty space via model intercomparison, we find that the CO₂ emissions and CO₂ prices vary convexly and nonlinearly with the discount rate and climate sensitivity over time. Accounting for this uncertainty is important for designing climate policies and carbon prices to accelerate the transition. In 70% of the scenarios, a 1.5 °C temperature overshoot was within this decade, calling for immediate policy action. Delaying this action by ten years may result in 2 °C mitigation costs being similar to those required to reach the 1.5 °C target if started today, with an immediate peak in emissions, a larger uncertainty in the medium-term horizon and a higher effort for net-zero emissions.

Original language	English
Article number	113642
Journal	Energy Policy
Volume	180
DOIs	https://doi.org/10.1016/j.enpol.2023.113642
Publication status	Published - Sept 2023
MoE publication type	A1 Journal article-refereed

Funding

This work has been performed within the project “Addressing Uncertainty in TIMES using Monte Carlo Methods” supported by the International Energy Agency Technology Collaboration Programme Energy Systems Technology Systems Analysis Programme (ETSAP) . The authors would also like to thank the anonymous reviewers for their constructive comments in improving the quality of the manuscript during the peer-review process.

Keywords

Clean technology investment risks
Climate policy uncertainty
Integrated assessment modelling
Monte Carlo analysis
Net-zero GHG emissions pathways
Sector coupling

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.enpol.2023.113642Licence: CC BY

Cite this

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title = "Deep decarbonisation pathways of the energy system in times of unprecedented uncertainty in the energy sector",

abstract = "Unprecedented investments in clean energy technology are required for a net-zero carbon energy system before temperatures breach the Paris Agreement goals. By performing a Monte-Carlo Analysis with the detailed ETSAP-TIAM Integrated Assessment Model and by generating 4000 scenarios of the world's energy system, climate and economy, we find that the uncertainty surrounding technology costs, resource potentials, climate sensitivity and the level of decoupling between energy demands and economic growth influence the efficiency of climate policies and accentuate investment risks in clean energy technologies. Contrary to other studies relying on exploring the uncertainty space via model intercomparison, we find that the CO2 emissions and CO2 prices vary convexly and nonlinearly with the discount rate and climate sensitivity over time. Accounting for this uncertainty is important for designing climate policies and carbon prices to accelerate the transition. In 70% of the scenarios, a 1.5 °C temperature overshoot was within this decade, calling for immediate policy action. Delaying this action by ten years may result in 2 °C mitigation costs being similar to those required to reach the 1.5 °C target if started today, with an immediate peak in emissions, a larger uncertainty in the medium-term horizon and a higher effort for net-zero emissions.",

keywords = "Clean technology investment risks, Climate policy uncertainty, Integrated assessment modelling, Monte Carlo analysis, Net-zero GHG emissions pathways, Sector coupling",

author = "Evangelos Panos and James Glynn and Socrates Kypreos and Antti Lehtil{\"a} and Xiufeng Yue and {{\'O} Gallach{\'o}ir}, Brian and David Daniels and Hancheng Dai",

note = "Funding Information: This work has been performed within the project “Addressing Uncertainty in TIMES using Monte Carlo Methods” supported by the International Energy Agency Technology Collaboration Programme Energy Systems Technology Systems Analysis Programme (ETSAP) . ",

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doi = "10.1016/j.enpol.2023.113642",

language = "English",

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AU - Panos, Evangelos

AU - Glynn, James

AU - Kypreos, Socrates

AU - Lehtilä, Antti

AU - Yue, Xiufeng

AU - Ó Gallachóir, Brian

AU - Daniels, David

AU - Dai, Hancheng

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N2 - Unprecedented investments in clean energy technology are required for a net-zero carbon energy system before temperatures breach the Paris Agreement goals. By performing a Monte-Carlo Analysis with the detailed ETSAP-TIAM Integrated Assessment Model and by generating 4000 scenarios of the world's energy system, climate and economy, we find that the uncertainty surrounding technology costs, resource potentials, climate sensitivity and the level of decoupling between energy demands and economic growth influence the efficiency of climate policies and accentuate investment risks in clean energy technologies. Contrary to other studies relying on exploring the uncertainty space via model intercomparison, we find that the CO2 emissions and CO2 prices vary convexly and nonlinearly with the discount rate and climate sensitivity over time. Accounting for this uncertainty is important for designing climate policies and carbon prices to accelerate the transition. In 70% of the scenarios, a 1.5 °C temperature overshoot was within this decade, calling for immediate policy action. Delaying this action by ten years may result in 2 °C mitigation costs being similar to those required to reach the 1.5 °C target if started today, with an immediate peak in emissions, a larger uncertainty in the medium-term horizon and a higher effort for net-zero emissions.

AB - Unprecedented investments in clean energy technology are required for a net-zero carbon energy system before temperatures breach the Paris Agreement goals. By performing a Monte-Carlo Analysis with the detailed ETSAP-TIAM Integrated Assessment Model and by generating 4000 scenarios of the world's energy system, climate and economy, we find that the uncertainty surrounding technology costs, resource potentials, climate sensitivity and the level of decoupling between energy demands and economic growth influence the efficiency of climate policies and accentuate investment risks in clean energy technologies. Contrary to other studies relying on exploring the uncertainty space via model intercomparison, we find that the CO2 emissions and CO2 prices vary convexly and nonlinearly with the discount rate and climate sensitivity over time. Accounting for this uncertainty is important for designing climate policies and carbon prices to accelerate the transition. In 70% of the scenarios, a 1.5 °C temperature overshoot was within this decade, calling for immediate policy action. Delaying this action by ten years may result in 2 °C mitigation costs being similar to those required to reach the 1.5 °C target if started today, with an immediate peak in emissions, a larger uncertainty in the medium-term horizon and a higher effort for net-zero emissions.

KW - Clean technology investment risks

KW - Climate policy uncertainty

KW - Integrated assessment modelling

KW - Monte Carlo analysis

KW - Net-zero GHG emissions pathways

KW - Sector coupling

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Deep decarbonisation pathways of the energy system in times of unprecedented uncertainty in the energy sector

Abstract

Funding

Keywords

UN SDGs

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