Roadmap on Quantum Thermodynamics

Journal article

Steve Campbell, Irene D'Amico, M. A. Ciampini, Janet Anders, Natalia Ares, Simone Artini, A. Auffèves, Lindsay Bassman Oftelie, Laetitia P. Bettmann, Marcus V. S. Bonancca, Thomas Busch, Michele Campisi, Moallison F. Cavalcante, Luis A. Correa, E. Cuestas, Ceren Dag, Salambô Dago, Sebastian Deffner, Adolfo del Campo, A. Deutschmann‐Olek, Sandro Donadi, Emery Doucet, C. Elouard, Klaus Ensslin, P. Erker, Nicole Fabbri, F. Fedele, Guilherme Fiusa, Thomás Fogarty, Joshua Folk, G. Guarnieri, Abhaya S. Hegde, Santiago Hern'andez-G'omez, Chang-Kang Hu, F. Iemini, B. Karimi, Nikolai Kiesel, G. Landi, A. Lasek, S. Lemziakov, Gabriele Lo Monaco, Eric Lutz, D. Lvov, O. Maillet, M. Mehboudi, Taysa M. Mendoncca, H. Miller, Andrew K. Mitchell, M. Mitchison, Victor Mukherjee, M. Paternostro, J. Pekola, M. Perarnau-Llobet, U. Poschinger, Alberto Rolandi, Dario Rosa, Rafael S'anchez, Alan C. Santos, R. Sarthour, E. Sela, Andrea Solfanelli, A. M. Souza, Janine Splettstoesser, Dian Tan, Ludovico Tesser, T. Vu, Artur Widera, N. Y. Halpern, Krissia Zawadzki
2025

Semantic Scholar ArXiv

Cite

APA Click to copy
Campbell, S., D'Amico, I., Ciampini, M. A., Anders, J., Ares, N., Artini, S., … Zawadzki, K. (2025). Roadmap on Quantum Thermodynamics.

Chicago/Turabian Click to copy
Campbell, Steve, Irene D'Amico, M. A. Ciampini, Janet Anders, Natalia Ares, Simone Artini, A. Auffèves, et al. “Roadmap on Quantum Thermodynamics” (2025).

MLA Click to copy
Campbell, Steve, et al. Roadmap on Quantum Thermodynamics. 2025.

BibTeX Click to copy

@article{steve2025a,
  title = {Roadmap on Quantum Thermodynamics},
  year = {2025},
  author = {Campbell, Steve and D'Amico, Irene and Ciampini, M. A. and Anders, Janet and Ares, Natalia and Artini, Simone and Auffèves, A. and Oftelie, Lindsay Bassman and Bettmann, Laetitia P. and Bonancca, Marcus V. S. and Busch, Thomas and Campisi, Michele and Cavalcante, Moallison F. and Correa, Luis A. and Cuestas, E. and Dag, Ceren and Dago, Salambô and Deffner, Sebastian and del Campo, Adolfo and Deutschmann‐Olek, A. and Donadi, Sandro and Doucet, Emery and Elouard, C. and Ensslin, Klaus and Erker, P. and Fabbri, Nicole and Fedele, F. and Fiusa, Guilherme and Fogarty, Thomás and Folk, Joshua and Guarnieri, G. and Hegde, Abhaya S. and Hern'andez-G'omez, Santiago and Hu, Chang-Kang and Iemini, F. and Karimi, B. and Kiesel, Nikolai and Landi, G. and Lasek, A. and Lemziakov, S. and Monaco, Gabriele Lo and Lutz, Eric and Lvov, D. and Maillet, O. and Mehboudi, M. and Mendoncca, Taysa M. and Miller, H. and Mitchell, Andrew K. and Mitchison, M. and Mukherjee, Victor and Paternostro, M. and Pekola, J. and Perarnau-Llobet, M. and Poschinger, U. and Rolandi, Alberto and Rosa, Dario and S'anchez, Rafael and Santos, Alan C. and Sarthour, R. and Sela, E. and Solfanelli, Andrea and Souza, A. M. and Splettstoesser, Janine and Tan, Dian and Tesser, Ludovico and Vu, T. and Widera, Artur and Halpern, N. Y. and Zawadzki, Krissia}
}

Abstract

The last two decades has seen quantum thermodynamics become a well established field of research in its own right. In that time, it has demonstrated a remarkably broad applicability, ranging from providing foundational advances in the understanding of how thermodynamic principles apply at the nano-scale and in the presence of quantum coherence, to providing a guiding framework for the development of efficient quantum devices. Exquisite levels of control have allowed state-of-the-art experimental platforms to explore energetics and thermodynamics at the smallest scales which has in turn helped to drive theoretical advances. This Roadmap provides an overview of the recent developments across many of the field's sub-disciplines, assessing the key challenges and future prospects, providing a guide for its near term progress.