Lifshitz transition enabling superconducting dome around a charge-order critical point

Roemer D.H. Hinlopen; Owen N. Moulding; William R. Broad; Jonathan Buhot; Femke Bangma; Alix McCollam; Jake Ayres; Charles J. Sayers; Enrico Da Como; Felix Flicker; Jasper van Wezel; Sven Friedemann

doi:10.1126/sciadv.adl3921

Lifshitz transition enabling superconducting dome around a charge-order critical point

Roemer D.H. Hinlopen, Owen N. Moulding, William R. Broad, Jonathan Buhot, Femke Bangma, Alix McCollam, Jake Ayres, Charles J. Sayers, Enrico Da Como, Felix Flicker, Jasper van Wezel, Sven Friedemann

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6 Citations (SciVal)

Abstract

Superconductivity often emerges as a dome around a quantum critical point (QCP) where long-range order is suppressed to zero temperature, mostly in magnetically ordered materials. However, the emergence of superconductivity at charge-order QCPs remains shrouded in mystery, despite its relevance to high-temperature superconductors and other exotic phases of matter. Here, we present resistance measurements proving that a dome of superconductivity surrounds the putative charge-density-wave QCP in pristine samples of titanium diselenide tuned with hydrostatic pressure. In addition, our quantum oscillation measurements combined with electronic structure calculations show that superconductivity sets in precisely when large electron and hole pockets suddenly appear through an abrupt change of the Fermi surface topology, also known as a Lifshitz transition. Combined with the known repulsive interaction, this suggests that unconventional s± superconductivity is mediated by charge-density-wave fluctuations in titanium diselenide. These results highlight the importance of the electronic ground state and charge fluctuations in enabling unconventional superconductivity.

Original language	English
Article number	adl3921
Pages (from-to)	eadl3921
Journal	Science Advances
Volume	10
Issue number	27
Early online date	5 Jul 2024
DOIs	https://doi.org/10.1126/sciadv.adl3921
Publication status	Published - 5 Jul 2024

Data Availability Statement

All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Numerical data are available to download at the University of Bristol data repository at https://doi.org/10.5523/bris.1ljqsum52meo02mb0phb2wp344.

Funding

We thank P. King, A. Carrington, and N. E. Hussey for discussions. Funding: This work was partially supported by the EPSRC under grants EP/L015544/1, EP/ N01085X/1, EP/X012239/1, and EP/N026691/1 and the ERC Horizon 2020 program under grant 715262-HPSuper. J.A. acknowledges the support of a Leverhulme Trust Early Career Fellowship. The work was supported by the HFML-RU member of the European Magnetic Field Laboratory (EMFL). Author contributions: Conceptualization: R.D.H.H., O.N.M., J.v.W., and S.F. Methodology: R.D.H.H., O.N.M., F.F., J.v.W., S.F., and E.D.C. Investigation: R.D.H.H., O.N.M., J.B., F.B., A.M., J.A., W.R.B., C.J.S., F.F., and S.F. Visualization: R.D.H.H., O.N.M., F.F., and S.F. Supervision: F.F., J.v.W., E.D.C., and S.F. Writing-original draft: R.D.H.H., O.N.M., and S.F. Writing-review and editing: R.D.H.H., O.N.M., J.A., E.D.C., F.F., J.v.W., and S.F. Competing interests: The authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Numerical data are available to download at the University of Bristol data repository at https://doi.org/10.5523/bris.1ljqsum52meo02mb0phb2wp344. Acknowledgments: We thank P. King, A. carrington, and n. e. Hussey for discussions. Funding: this work was partially supported by the ePSRc under grants eP/l015544/1, eP/ n01085X/1, eP/X012239/1, and eP/n026691/1 and the eRc Horizon 2020 program under grant 715262-HPSuper. J.A. acknowledges the support of a leverhulme trust early career Fellowship. the work was supported by the HFMl-RU member of the european Magnetic Field laboratory (eMFl). Author contributions: conceptualization: R.d.H.H., O.n.M., J.v.W., and S.F. Methodology: R.d.H.H., O.n.M., F.F., J.v.W., S.F., and e.d.c. investigation: R.d.H.H., O.n.M., J.B., F.B., A.M., J.A., W.R.B., c.J.S., F.F., and S.F. visualization: R.d.H.H., O.n.M., F.F., and S.F. Supervision: F.F., J.v.W., e.d.c., and S.F. Writing\u2014original draft: R.d.H.H., O.n.M., and S.F. Writing\u2014review and editing: R.d.H.H., O.n.M., J.A., e.d.c., F.F., J.v.W., and S.F. Competing interests: the authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. numerical data are available to download at the University of Bristol data repository at https://doi.org/10.5523/bris.1ljqsum52meo02mb0phb2wp344.

Funders	Funder number
ERC Horizon 2020 program
The Leverhulme Trust
HFML-RU
Engineering and Physical Sciences Research Council	EP/ N01085X/1, EP/X012239/1, EP/N026691/1, EP/L015544/1

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title = "Lifshitz transition enabling superconducting dome around a charge-order critical point",

abstract = "Superconductivity often emerges as a dome around a quantum critical point (QCP) where long-range order is suppressed to zero temperature, mostly in magnetically ordered materials. However, the emergence of superconductivity at charge-order QCPs remains shrouded in mystery, despite its relevance to high-temperature superconductors and other exotic phases of matter. Here, we present resistance measurements proving that a dome of superconductivity surrounds the putative charge-density-wave QCP in pristine samples of titanium diselenide tuned with hydrostatic pressure. In addition, our quantum oscillation measurements combined with electronic structure calculations show that superconductivity sets in precisely when large electron and hole pockets suddenly appear through an abrupt change of the Fermi surface topology, also known as a Lifshitz transition. Combined with the known repulsive interaction, this suggests that unconventional s± superconductivity is mediated by charge-density-wave fluctuations in titanium diselenide. These results highlight the importance of the electronic ground state and charge fluctuations in enabling unconventional superconductivity.",

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AU - Hinlopen, Roemer D.H.

AU - Moulding, Owen N.

AU - Broad, William R.

AU - Buhot, Jonathan

AU - Bangma, Femke

AU - McCollam, Alix

AU - Ayres, Jake

AU - Sayers, Charles J.

AU - Da Como, Enrico

AU - Flicker, Felix

AU - van Wezel, Jasper

AU - Friedemann, Sven

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N2 - Superconductivity often emerges as a dome around a quantum critical point (QCP) where long-range order is suppressed to zero temperature, mostly in magnetically ordered materials. However, the emergence of superconductivity at charge-order QCPs remains shrouded in mystery, despite its relevance to high-temperature superconductors and other exotic phases of matter. Here, we present resistance measurements proving that a dome of superconductivity surrounds the putative charge-density-wave QCP in pristine samples of titanium diselenide tuned with hydrostatic pressure. In addition, our quantum oscillation measurements combined with electronic structure calculations show that superconductivity sets in precisely when large electron and hole pockets suddenly appear through an abrupt change of the Fermi surface topology, also known as a Lifshitz transition. Combined with the known repulsive interaction, this suggests that unconventional s± superconductivity is mediated by charge-density-wave fluctuations in titanium diselenide. These results highlight the importance of the electronic ground state and charge fluctuations in enabling unconventional superconductivity.

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Lifshitz transition enabling superconducting dome around a charge-order critical point

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