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How might quantum computing impact climate change and the wider environment?

Published online by Cambridge University Press:  18 February 2025

Klara Theophilo  and
Natasha Oughton
Klara Theophilo*
Affiliation:
National Quantum Computing Centre, Rutherford Appleton Laboratory, Didcot, UK
Natasha Oughton
Affiliation:
National Quantum Computing Centre, Rutherford Appleton Laboratory, Didcot, UK
*
Corresponding author: Klara Theophilo; Email: [email protected]
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Extract

Quantum computing’s potential impact on climate and the environment is of great importance and taking steps to shape its trajectory towards sustainability and positive impact, at this stage, is vital for responsible development. In this question, we suggest areas for investigation to build shared understanding and advance sustainable development.

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Research Directions: Quantum Technologies , Volume 3 , 2025 , e4
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
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© Crown Copyright - STFC - Science and Technology Facilities Council and the Author(s), 2025. Published by Cambridge University Press

Context

Quantum computing’s potential impact on climate and the environment is of great importance and taking steps to shape its trajectory towards sustainability and positive impact, at this stage, is vital for responsible development. In this question, we suggest areas for investigation to build shared understanding and advance sustainable development.

There are two dimensions to consider in understanding quantum computing’s environmental and climate impact. First is the direct environmental impact of developing and using quantum computers throughout their life-cycle, including, for example, resource requirements and carbon footprint (Arora and Kumar, Reference Arora and Kumar2024). Second is the possibility of quantum computing use cases targeted towards climate solutions (Berger et al., Reference Berger2021; Paudel et al., Reference Paudel, Syamlal, Crawford, Lee, Shugayev, Lu, Ohodnicki, Mollot and Duan2022; Ho et al., Reference Ho, Chen, Lee, Burt, Yu and Lee2024).

Although there have been initial steps towards investigating the energy requirements of quantum computing (see Auffèves, Reference Auffèves2022; Meier and Yamasaki, Reference Meier and Yamasaki2023), we need to understand better the environmental impact of the full life-cycle of developing, using and disposing of quantum computers. This includes factors such as energy and water consumption, carbon footprint, waste disposal and recycling, and mineral use.

This initial research suggests quantum computing may provide advantages, reducing environmental cost when compared to, for example, high-performance computing (HPC). Though the current expectation is that quantum computers may require significantly lower energy than their classical counterparts to solve certain classes of problems (Arute et al., Reference Arute, Arya, Babbush, Bacon, Bardin, Barends, Biswas, Boixo, Brandao, Buell, Burkett, Chen, Chen, Chiaro, Collins, Courtney, Dunsworth, Farhi, Foxen, Fowler, Gidney, Giustina, Graff, Guerin, Habegger, Harrigan, Hartmann, Ho, Hoffmann, Huang, Humble, Isakov, Jeffrey, Jiang, Kafri, Kechedzhi, Kelly, Klimov, Knysh, Korotkov, Kostritsa, Landhuis, Lindmark, Lucero, Lyakh, Mandrà, McClean, McEwen, Megrant, Mi, Michielsen, Mohseni, Mutus, Naaman, Neeley, Neill, Niu, Ostby, Petukhov, Platt, Quintana, Rieffel, Roushan, Rubin, Sank, Satzinger, Smelyanskiy, Sung, Trevithick, Vainsencher, Villalonga, White, Yao, Yeh, Zalcman, Neven and Martinis2019; Meier and Yamasaki, Reference Meier and Yamasaki2023), it is first necessary to define and agree upon metrics to quantify these resources to properly claim this advantage.

For example, there remains a lack of community consensus on a quantum computing analogue to the classical concept of floating point operations per second (see, e.g., Reference NayakNayak; Reference CampbellCampbell for alternative proposals). As a result, quantifying the energy efficiency of a quantum computer is a challenge. Defining community-accepted metrics for this and other environmentally relevant metrics remains an open question.

Additionally, the support requirements for quantum computing systems, for example, cryogenic cooling, are themselves currently resource intensive, and therefore when calculating overall resource requirements, must be accounted for. Another open question is how resources utilisation scales for a useful quantum computer.

The second dimension to consider is the potential of quantum computing to address climate and other environmental challenges. A few highlighted examples (by no means an exhaustive list) are:

Despite quantum computing’s promoted potential, it remains unclear what impact these applications may have, as well as the timeline on which they may be feasible. A fuller understanding is required as is benchmarking of these quantum computing applications against the performance of current classical capabilities, including HPC. This is crucial to enable decision-makers, such as policy makers and funders, to choose the most promising applications to focus efforts and resources on. Since climate interventions are pressing, in some cases a particular intervention may be needed on a timescale which is not compatible with current projections on quantum computing’s development. Transparency on current capabilities and expectations will help to ensure that research efforts, funding and other resources are not inappropriately directed towards quantum computing when a classical approach may be more appropriate.

Better understanding of the applications, benefits and environmental impact of the life cycle of quantum computers would help identify and perform appropriate actions to address climate and broader environmental challenges at this crucial moment of development. Associated research questions therefore include:

  • The identification and assessment of use cases targeted towards climate and wider environmental challenges, and investigation into the extent to which they may help and the timeframe for doing so.

  • Relevant metrics for quantifying energy efficiency when performing quantum computation.

  • Identification of other environmentally relevant metrics across the full life cycle of quantum computing systems

  • Proposals for means of effectively communicating key information about applications of quantum computing for climate change and wider environmental issues, including impact, timeline, comparisons with classical methods, and relevance, particularly for decision-makers, including policymakers and funders.

How to contribute to this Question

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Competing interests

The author(s) declare none.

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