Demand-side strategies enable rapid and deep cuts in buildings and transport emissions to 2050

Rik van Heerden; Oreane Y. Edelenbosch; Vassilis Daioglou; Thomas Le Gallic; Luiz Bernardo Baptista; Alice Di Bella; Francesco Pietro Colelli; Johannes Emmerling; Panagiotis Fragkos; Robin Hasse; Johanna Hoppe; Paul Kishimoto; Florian Leblanc; Julien Lefèvre; Gunnar Luderer; Giacomo Marangoni; Alessio Mastrucci; Hazel Pettifor; Robert Pietzcker; Pedro Rochedo; Bas van Ruijven; Roberto Schaeffer; Charlie Wilson; Sonia Yeh; Eleftheria Zisarou; Detlef van Vuuren

doi:10.1038/s41560-025-01703-1

Demand-side strategies enable rapid and deep cuts in buildings and transport emissions to 2050

Rik van Heerden
, Oreane Y. Edelenbosch
, Vassilis Daioglou
, Thomas Le Gallic
, Luiz Bernardo Baptista
, Alice Di Bella
, Francesco Pietro Colelli
, Johannes Emmerling
, Panagiotis Fragkos
, Robin Hasse
, Johanna Hoppe
, Paul Kishimoto
, Florian Leblanc
, Julien Lefèvre
, Gunnar Luderer
, Giacomo Marangoni
, Alessio Mastrucci
, Hazel Pettifor
, Robert Pietzcker
, Pedro Rochedo

Bas van Ruijven, Roberto Schaeffer, Charlie Wilson, Sonia Yeh, Eleftheria Zisarou, Detlef van Vuuren

Management Science & Engineering

Universidade Federal do Rio de Janeiro
CMCC
Politecnico di Milano
Università Ca' Foscari Venezia
TU-Berlin
International Institute of Applied Systems Analysis
Delft University of Technology
University of Oxford
Chalmers University of Technology

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

46 Scopus citations

Abstract

Decarbonization of energy-using sectors is essential for tackling climate change. We use an ensemble of global integrated assessment models to assess CO₂ emissions reduction potentials in buildings and transport, accounting for system interactions. We focus on three intervention strategies with distinct emphases: reducing or changing activity, improving technological efficiency and electrifying energy end use. We find that these strategies can reduce emissions by 51–85% in buildings and 37–91% in transport by 2050 relative to a current policies scenario (ranges indicate model variability). Electrification has the largest potential for direct emissions reductions in both sectors. Interactions between the policies and measures that comprise the three strategies have a modest overall effect on mitigation potentials. However, combining different strategies is strongly beneficial from an energy system perspective as lower electricity demand reduces the need for costly supply-side investments and infrastructure.

Original language	British English
Article number	3077
Pages (from-to)	380-394
Number of pages	15
Journal	Nature Energy
Volume	10
Issue number	3
DOIs	https://doi.org/10.1038/s41560-025-01703-1
State	Published - Mar 2025

UN SDGs

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

SDG 9 Industry, Innovation, and Infrastructure
SDG 13 Climate Action

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van Heerden, R., Edelenbosch, O. Y., Daioglou, V., Le Gallic, T., Baptista, L. B., Di Bella, A., Colelli, F. P., Emmerling, J., Fragkos, P., Hasse, R., Hoppe, J., Kishimoto, P., Leblanc, F., Lefèvre, J., Luderer, G., Marangoni, G., Mastrucci, A., Pettifor, H., Pietzcker, R., ... van Vuuren, D. (2025). Demand-side strategies enable rapid and deep cuts in buildings and transport emissions to 2050. Nature Energy, 10(3), 380-394. Article 3077. https://doi.org/10.1038/s41560-025-01703-1

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abstract = "Decarbonization of energy-using sectors is essential for tackling climate change. We use an ensemble of global integrated assessment models to assess CO2 emissions reduction potentials in buildings and transport, accounting for system interactions. We focus on three intervention strategies with distinct emphases: reducing or changing activity, improving technological efficiency and electrifying energy end use. We find that these strategies can reduce emissions by 51–85\% in buildings and 37–91\% in transport by 2050 relative to a current policies scenario (ranges indicate model variability). Electrification has the largest potential for direct emissions reductions in both sectors. Interactions between the policies and measures that comprise the three strategies have a modest overall effect on mitigation potentials. However, combining different strategies is strongly beneficial from an energy system perspective as lower electricity demand reduces the need for costly supply-side investments and infrastructure.",

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van Heerden, R, Edelenbosch, OY, Daioglou, V, Le Gallic, T, Baptista, LB, Di Bella, A, Colelli, FP, Emmerling, J, Fragkos, P, Hasse, R, Hoppe, J, Kishimoto, P, Leblanc, F, Lefèvre, J, Luderer, G, Marangoni, G, Mastrucci, A, Pettifor, H, Pietzcker, R, Rochedo, P, van Ruijven, B, Schaeffer, R, Wilson, C, Yeh, S, Zisarou, E & van Vuuren, D 2025, 'Demand-side strategies enable rapid and deep cuts in buildings and transport emissions to 2050', Nature Energy, vol. 10, no. 3, 3077, pp. 380-394. https://doi.org/10.1038/s41560-025-01703-1

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AU - Edelenbosch, Oreane Y.

AU - Daioglou, Vassilis

AU - Le Gallic, Thomas

AU - Baptista, Luiz Bernardo

AU - Di Bella, Alice

AU - Colelli, Francesco Pietro

AU - Emmerling, Johannes

AU - Fragkos, Panagiotis

AU - Hasse, Robin

AU - Hoppe, Johanna

AU - Kishimoto, Paul

AU - Leblanc, Florian

AU - Lefèvre, Julien

AU - Luderer, Gunnar

AU - Marangoni, Giacomo

AU - Mastrucci, Alessio

AU - Pettifor, Hazel

AU - Pietzcker, Robert

AU - Rochedo, Pedro

AU - van Ruijven, Bas

AU - Schaeffer, Roberto

AU - Wilson, Charlie

AU - Yeh, Sonia

AU - Zisarou, Eleftheria

AU - van Vuuren, Detlef

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AB - Decarbonization of energy-using sectors is essential for tackling climate change. We use an ensemble of global integrated assessment models to assess CO2 emissions reduction potentials in buildings and transport, accounting for system interactions. We focus on three intervention strategies with distinct emphases: reducing or changing activity, improving technological efficiency and electrifying energy end use. We find that these strategies can reduce emissions by 51–85% in buildings and 37–91% in transport by 2050 relative to a current policies scenario (ranges indicate model variability). Electrification has the largest potential for direct emissions reductions in both sectors. Interactions between the policies and measures that comprise the three strategies have a modest overall effect on mitigation potentials. However, combining different strategies is strongly beneficial from an energy system perspective as lower electricity demand reduces the need for costly supply-side investments and infrastructure.

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EP - 394

JO - Nature Energy

JF - Nature Energy

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M1 - 3077

ER -

Demand-side strategies enable rapid and deep cuts in buildings and transport emissions to 2050

Abstract

UN SDGs

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