The 2021 room-temperature superconductivity roadmap

Lilia Boeri; Richard Hennig; Peter Hirschfeld; Gianni Profeta; Antonio Sanna; Eva Zurek; Warren E. Pickett; Maximilian Amsler; Ranga Dias; Mikhail I. Eremets; Christoph Heil; Russell J. Hemley; Hanyu Liu; Yanming Ma; Carlo Pierleoni; Aleksey N. Kolmogorov; Nikita Rybin; Dmitry Novoselov; Vladimir Anisimov; Artem R. Oganov; Chris J. Pickard; Tiange Bi; Ryotaro Arita; Ion Errea; Camilla Pellegrini; Ryan Requist; E. K.U. Gross; Elena Roxana Margine; Stephen R. Xie; Yundi Quan; Ajinkya Hire; Laura Fanfarillo; G. R. Stewart; J. J. Hamlin; Valentin Stanev; Renato S. Gonnelli; Erik Piatti; Davide Romanin; Dario Daghero; Roser Valenti

doi:10.1088/1361-648X/ac2864

The 2021 room-temperature superconductivity roadmap

Lilia Boeri
, Richard Hennig
, Peter Hirschfeld
, Gianni Profeta
, Antonio Sanna
, Eva Zurek
, Warren E. Pickett
, Maximilian Amsler
, Ranga Dias
, Mikhail I. Eremets
, Christoph Heil
, Russell J. Hemley
, Hanyu Liu
, Yanming Ma
, Carlo Pierleoni
, Aleksey N. Kolmogorov
, Nikita Rybin
, Dmitry Novoselov
, Vladimir Anisimov
, Artem R. Oganov

Chris J. Pickard, Tiange Bi, Ryotaro Arita, Ion Errea, Camilla Pellegrini, Ryan Requist, E. K.U. Gross, Elena Roxana Margine, Stephen R. Xie, Yundi Quan, Ajinkya Hire, Laura Fanfarillo, G. R. Stewart, J. J. Hamlin, Valentin Stanev, Renato S. Gonnelli, Erik Piatti, Davide Romanin, Dario Daghero, Roser Valenti

Chemistry

University of Rome La Sapienza
University of Florida
University of L'Aquila
Max Planck Institute of Microstructure Physics
University of California at Davis
University of Bern
Cornell University
University of Rochester
Max Planck Institute for Chemistry
Graz University of Technology
University of Illinois at Chicago
Jilin University
State University of New York Binghamton University
Ural Federal University
Skolkovo Institute of Science and Technology
University of Cambridge
SUNY Buffalo
The University of Tokyo
RIKEN
University of the Basque Country
University of Perugia
Hebrew University of Jerusalem
International School for Advanced Studies
University of Maryland, College Park
Polytechnic University of Turin
Sorbonne Université
Goethe University Frankfurt

Research output: Contribution to journal › Review article › peer-review

215 Scopus citations

Abstract

Designing materials with advanced functionalities is the main focus of contemporary solid-state physics and chemistry. Research efforts worldwide are funneled into a few high-end goals, one of the oldest, and most fascinating of which is the search for an ambient temperature superconductor (A-SC). The reason is clear: superconductivity at ambient conditions implies being able to handle, measure and access a single, coherent, macroscopic quantum mechanical state without the limitations associated with cryogenics and pressurization. This would not only open exciting avenues for fundamental research, but also pave the road for a wide range of technological applications, affecting strategic areas such as energy conservation and climate change. In this roadmap we have collected contributions from many of the main actors working on superconductivity, and asked them to share their personal viewpoint on the field. The hope is that this article will serve not only as an instantaneous picture of the status of research, but also as a true roadmap defining the main long-term theoretical and experimental challenges that lie ahead. Interestingly, although the current research in superconductor design is dominated by conventional (phonon-mediated) superconductors, there seems to be a widespread consensus that achieving A-SC may require different pairing mechanisms. In memoriam, to Neil Ashcroft, who inspired us all.

Original language	English
Article number	183002
Journal	Journal of Physics Condensed Matter
Volume	34
Issue number	18
DOIs	https://doi.org/10.1088/1361-648X/ac2864
State	Published - May 4 2022

Keywords

crystal structure prediction
electron-phonon interaction
hydrides
novel superconductors
superconductivity
superconductor

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10.1088/1361-648X/ac2864

Cite this

Boeri, L., Hennig, R., Hirschfeld, P., Profeta, G., Sanna, A., Zurek, E., Pickett, W. E., Amsler, M., Dias, R., Eremets, M. I., Heil, C., Hemley, R. J., Liu, H., Ma, Y., Pierleoni, C., Kolmogorov, A. N., Rybin, N., Novoselov, D., Anisimov, V., ... Valenti, R. (2022). The 2021 room-temperature superconductivity roadmap. Journal of Physics Condensed Matter, 34(18), Article 183002. https://doi.org/10.1088/1361-648X/ac2864

@article{d10dec54e4424b058c527e38373a050e,

title = "The 2021 room-temperature superconductivity roadmap",

abstract = "Designing materials with advanced functionalities is the main focus of contemporary solid-state physics and chemistry. Research efforts worldwide are funneled into a few high-end goals, one of the oldest, and most fascinating of which is the search for an ambient temperature superconductor (A-SC). The reason is clear: superconductivity at ambient conditions implies being able to handle, measure and access a single, coherent, macroscopic quantum mechanical state without the limitations associated with cryogenics and pressurization. This would not only open exciting avenues for fundamental research, but also pave the road for a wide range of technological applications, affecting strategic areas such as energy conservation and climate change. In this roadmap we have collected contributions from many of the main actors working on superconductivity, and asked them to share their personal viewpoint on the field. The hope is that this article will serve not only as an instantaneous picture of the status of research, but also as a true roadmap defining the main long-term theoretical and experimental challenges that lie ahead. Interestingly, although the current research in superconductor design is dominated by conventional (phonon-mediated) superconductors, there seems to be a widespread consensus that achieving A-SC may require different pairing mechanisms. In memoriam, to Neil Ashcroft, who inspired us all.",

keywords = "crystal structure prediction, electron-phonon interaction, hydrides, novel superconductors, superconductivity, superconductor",

author = "Lilia Boeri and Richard Hennig and Peter Hirschfeld and Gianni Profeta and Antonio Sanna and Eva Zurek and Pickett, \{Warren E.\} and Maximilian Amsler and Ranga Dias and Eremets, \{Mikhail I.\} and Christoph Heil and Hemley, \{Russell J.\} and Hanyu Liu and Yanming Ma and Carlo Pierleoni and Kolmogorov, \{Aleksey N.\} and Nikita Rybin and Dmitry Novoselov and Vladimir Anisimov and Oganov, \{Artem R.\} and Pickard, \{Chris J.\} and Tiange Bi and Ryotaro Arita and Ion Errea and Camilla Pellegrini and Ryan Requist and Gross, \{E. K.U.\} and Margine, \{Elena Roxana\} and Xie, \{Stephen R.\} and Yundi Quan and Ajinkya Hire and Laura Fanfarillo and Stewart, \{G. R.\} and Hamlin, \{J. J.\} and Valentin Stanev and Gonnelli, \{Renato S.\} and Erik Piatti and Davide Romanin and Dario Daghero and Roser Valenti",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s). Published by IOP Publishing Ltd.",

year = "2022",

month = may,

day = "4",

doi = "10.1088/1361-648X/ac2864",

language = "English",

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Boeri, L, Hennig, R, Hirschfeld, P, Profeta, G, Sanna, A, Zurek, E, Pickett, WE, Amsler, M, Dias, R, Eremets, MI, Heil, C, Hemley, RJ, Liu, H, Ma, Y, Pierleoni, C, Kolmogorov, AN, Rybin, N, Novoselov, D, Anisimov, V, Oganov, AR, Pickard, CJ, Bi, T, Arita, R, Errea, I, Pellegrini, C, Requist, R, Gross, EKU, Margine, ER, Xie, SR, Quan, Y, Hire, A, Fanfarillo, L, Stewart, GR, Hamlin, JJ, Stanev, V, Gonnelli, RS, Piatti, E, Romanin, D, Daghero, D & Valenti, R 2022, 'The 2021 room-temperature superconductivity roadmap', Journal of Physics Condensed Matter, vol. 34, no. 18, 183002. https://doi.org/10.1088/1361-648X/ac2864

TY - JOUR

T1 - The 2021 room-temperature superconductivity roadmap

AU - Boeri, Lilia

AU - Hennig, Richard

AU - Hirschfeld, Peter

AU - Profeta, Gianni

AU - Sanna, Antonio

AU - Zurek, Eva

AU - Pickett, Warren E.

AU - Amsler, Maximilian

AU - Dias, Ranga

AU - Eremets, Mikhail I.

AU - Heil, Christoph

AU - Hemley, Russell J.

AU - Liu, Hanyu

AU - Ma, Yanming

AU - Pierleoni, Carlo

AU - Kolmogorov, Aleksey N.

AU - Rybin, Nikita

AU - Novoselov, Dmitry

AU - Anisimov, Vladimir

AU - Oganov, Artem R.

AU - Pickard, Chris J.

AU - Bi, Tiange

AU - Arita, Ryotaro

AU - Errea, Ion

AU - Pellegrini, Camilla

AU - Requist, Ryan

AU - Gross, E. K.U.

AU - Margine, Elena Roxana

AU - Xie, Stephen R.

AU - Quan, Yundi

AU - Hire, Ajinkya

AU - Fanfarillo, Laura

AU - Stewart, G. R.

AU - Hamlin, J. J.

AU - Stanev, Valentin

AU - Gonnelli, Renato S.

AU - Piatti, Erik

AU - Romanin, Davide

AU - Daghero, Dario

AU - Valenti, Roser

PY - 2022/5/4

Y1 - 2022/5/4

N2 - Designing materials with advanced functionalities is the main focus of contemporary solid-state physics and chemistry. Research efforts worldwide are funneled into a few high-end goals, one of the oldest, and most fascinating of which is the search for an ambient temperature superconductor (A-SC). The reason is clear: superconductivity at ambient conditions implies being able to handle, measure and access a single, coherent, macroscopic quantum mechanical state without the limitations associated with cryogenics and pressurization. This would not only open exciting avenues for fundamental research, but also pave the road for a wide range of technological applications, affecting strategic areas such as energy conservation and climate change. In this roadmap we have collected contributions from many of the main actors working on superconductivity, and asked them to share their personal viewpoint on the field. The hope is that this article will serve not only as an instantaneous picture of the status of research, but also as a true roadmap defining the main long-term theoretical and experimental challenges that lie ahead. Interestingly, although the current research in superconductor design is dominated by conventional (phonon-mediated) superconductors, there seems to be a widespread consensus that achieving A-SC may require different pairing mechanisms. In memoriam, to Neil Ashcroft, who inspired us all.

AB - Designing materials with advanced functionalities is the main focus of contemporary solid-state physics and chemistry. Research efforts worldwide are funneled into a few high-end goals, one of the oldest, and most fascinating of which is the search for an ambient temperature superconductor (A-SC). The reason is clear: superconductivity at ambient conditions implies being able to handle, measure and access a single, coherent, macroscopic quantum mechanical state without the limitations associated with cryogenics and pressurization. This would not only open exciting avenues for fundamental research, but also pave the road for a wide range of technological applications, affecting strategic areas such as energy conservation and climate change. In this roadmap we have collected contributions from many of the main actors working on superconductivity, and asked them to share their personal viewpoint on the field. The hope is that this article will serve not only as an instantaneous picture of the status of research, but also as a true roadmap defining the main long-term theoretical and experimental challenges that lie ahead. Interestingly, although the current research in superconductor design is dominated by conventional (phonon-mediated) superconductors, there seems to be a widespread consensus that achieving A-SC may require different pairing mechanisms. In memoriam, to Neil Ashcroft, who inspired us all.

KW - crystal structure prediction

KW - electron-phonon interaction

KW - hydrides

KW - novel superconductors

KW - superconductivity

KW - superconductor

UR - https://www.scopus.com/pages/publications/85125552784

U2 - 10.1088/1361-648X/ac2864

DO - 10.1088/1361-648X/ac2864

M3 - Review article

C2 - 34544070

AN - SCOPUS:85125552784

SN - 0953-8984

VL - 34

JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

IS - 18

M1 - 183002

ER -

The 2021 room-temperature superconductivity roadmap

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Keywords

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