Direct observation of a uniaxial stress-driven Lifshitz transition in Sr2RuO4

Veronika Sunko; Edgar Abarca Morales; Igor Marković; Mark E. Barber; Dijana Milosavljević; Federico Mazzola; Dmitry A. Sokolov; Naoki Kikugawa; Cephise Cacho; Pavel Dudin; Helge Rosner; Clifford W. Hicks; Philip D.C. King; Andrew P. Mackenzie

doi:10.1038/s41535-019-0185-9

Direct observation of a uniaxial stress-driven Lifshitz transition in Sr₂RuO₄

Veronika Sunko, Edgar Abarca Morales, Igor Marković, Mark E. Barber, Dijana Milosavljević, Federico Mazzola, Dmitry A. Sokolov, Naoki Kikugawa, Cephise Cacho, Pavel Dudin, Helge Rosner, Clifford W. Hicks^*, Philip D.C. King, Andrew P. Mackenzie

^*Corresponding author for this work

Physics and Astronomy

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

45 Citations (Scopus)

Abstract

Pressure represents a clean tuning parameter for traversing the complex phase diagrams of interacting electron systems, and as such has proved of key importance in the study of quantum materials. Application of controlled uniaxial pressure has recently been shown to more than double the transition temperature of the unconventional superconductor Sr₂RuO₄, leading to a pronounced peak in T_c versus strain whose origin is still under active debate. Here we develop a simple and compact method to passively apply large uniaxial pressures in restricted sample environments, and utilise this to study the evolution of the electronic structure of Sr₂RuO₄ using angle-resolved photoemission. We directly visualise how uniaxial stress drives a Lifshitz transition of the γ-band Fermi surface, pointing to the key role of strain-tuning its associated van Hove singularity to the Fermi level in mediating the peak in T_c. Our measurements provide stringent constraints for theoretical models of the strain-tuned electronic structure evolution of Sr₂RuO₄. More generally, our experimental approach opens the door to future studies of strain-tuned phase transitions not only using photoemission but also other experimental techniques where large pressure cells or piezoelectric-based devices may be difficult to implement.

Original language	English
Article number	46
Journal	npj Quantum Materials
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s41535-019-0185-9
Publication status	Published - 1 Dec 2019

Bibliographical note

Funding Information:
We thank T. Kim and M. Watson for useful discussions, and U. Nitzsche (IFW Dresden) for support with computational facilities. We gratefully acknowledge support from the European Research Council (Grant no. ERC-714193-QUESTDO), the Royal Society, the Max-Planck Society and the International Max-Planck Partnership for Measurement and Observation at the Quantum Limit. V.S. acknowledges EPSRC for PhD studentship support through grant number EP/L015110/1. E.A.M. and I.M. acknowledge PhD studentship support from the IMPRS for the Chemistry and Physics of Quantum Materials. N.K. acknowledges the support from JSPS KAKENHI (Nos. JP17H06136 and JP18K04715) and JST-Mirai Programme (No. JPMJMI18A3) in Japan. We thank Diamond Light Source for access to beamline I05 (Proposal no. SI20427), which contributed to the results presented here.

Publisher Copyright:
© 2019, The Author(s).

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

Access to Document

10.1038/s41535-019-0185-9

Cite this

Sunko, V., Abarca Morales, E., Marković, I., Barber, M. E., Milosavljević, D., Mazzola, F., Sokolov, D. A., Kikugawa, N., Cacho, C., Dudin, P., Rosner, H., Hicks, C. W., King, P. D. C., & Mackenzie, A. P. (2019). Direct observation of a uniaxial stress-driven Lifshitz transition in Sr₂RuO₄. npj Quantum Materials, 4(1), Article 46. https://doi.org/10.1038/s41535-019-0185-9

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title = "Direct observation of a uniaxial stress-driven Lifshitz transition in Sr2RuO4",

abstract = "Pressure represents a clean tuning parameter for traversing the complex phase diagrams of interacting electron systems, and as such has proved of key importance in the study of quantum materials. Application of controlled uniaxial pressure has recently been shown to more than double the transition temperature of the unconventional superconductor Sr2RuO4, leading to a pronounced peak in Tc versus strain whose origin is still under active debate. Here we develop a simple and compact method to passively apply large uniaxial pressures in restricted sample environments, and utilise this to study the evolution of the electronic structure of Sr2RuO4 using angle-resolved photoemission. We directly visualise how uniaxial stress drives a Lifshitz transition of the γ-band Fermi surface, pointing to the key role of strain-tuning its associated van Hove singularity to the Fermi level in mediating the peak in Tc. Our measurements provide stringent constraints for theoretical models of the strain-tuned electronic structure evolution of Sr2RuO4. More generally, our experimental approach opens the door to future studies of strain-tuned phase transitions not only using photoemission but also other experimental techniques where large pressure cells or piezoelectric-based devices may be difficult to implement.",

author = "Veronika Sunko and {Abarca Morales}, Edgar and Igor Markovi{\'c} and Barber, {Mark E.} and Dijana Milosavljevi{\'c} and Federico Mazzola and Sokolov, {Dmitry A.} and Naoki Kikugawa and Cephise Cacho and Pavel Dudin and Helge Rosner and Hicks, {Clifford W.} and King, {Philip D.C.} and Mackenzie, {Andrew P.}",

note = "Funding Information: We thank T. Kim and M. Watson for useful discussions, and U. Nitzsche (IFW Dresden) for support with computational facilities. We gratefully acknowledge support from the European Research Council (Grant no. ERC-714193-QUESTDO), the Royal Society, the Max-Planck Society and the International Max-Planck Partnership for Measurement and Observation at the Quantum Limit. V.S. acknowledges EPSRC for PhD studentship support through grant number EP/L015110/1. E.A.M. and I.M. acknowledge PhD studentship support from the IMPRS for the Chemistry and Physics of Quantum Materials. N.K. acknowledges the support from JSPS KAKENHI (Nos. JP17H06136 and JP18K04715) and JST-Mirai Programme (No. JPMJMI18A3) in Japan. We thank Diamond Light Source for access to beamline I05 (Proposal no. SI20427), which contributed to the results presented here. Publisher Copyright: {\textcopyright} 2019, The Author(s).",

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AU - Sunko, Veronika

AU - Abarca Morales, Edgar

AU - Marković, Igor

AU - Barber, Mark E.

AU - Milosavljević, Dijana

AU - Mazzola, Federico

AU - Sokolov, Dmitry A.

AU - Kikugawa, Naoki

AU - Cacho, Cephise

AU - Dudin, Pavel

AU - Rosner, Helge

AU - Hicks, Clifford W.

AU - King, Philip D.C.

AU - Mackenzie, Andrew P.

N1 - Funding Information: We thank T. Kim and M. Watson for useful discussions, and U. Nitzsche (IFW Dresden) for support with computational facilities. We gratefully acknowledge support from the European Research Council (Grant no. ERC-714193-QUESTDO), the Royal Society, the Max-Planck Society and the International Max-Planck Partnership for Measurement and Observation at the Quantum Limit. V.S. acknowledges EPSRC for PhD studentship support through grant number EP/L015110/1. E.A.M. and I.M. acknowledge PhD studentship support from the IMPRS for the Chemistry and Physics of Quantum Materials. N.K. acknowledges the support from JSPS KAKENHI (Nos. JP17H06136 and JP18K04715) and JST-Mirai Programme (No. JPMJMI18A3) in Japan. We thank Diamond Light Source for access to beamline I05 (Proposal no. SI20427), which contributed to the results presented here. Publisher Copyright: © 2019, The Author(s).

PY - 2019/12/1

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N2 - Pressure represents a clean tuning parameter for traversing the complex phase diagrams of interacting electron systems, and as such has proved of key importance in the study of quantum materials. Application of controlled uniaxial pressure has recently been shown to more than double the transition temperature of the unconventional superconductor Sr2RuO4, leading to a pronounced peak in Tc versus strain whose origin is still under active debate. Here we develop a simple and compact method to passively apply large uniaxial pressures in restricted sample environments, and utilise this to study the evolution of the electronic structure of Sr2RuO4 using angle-resolved photoemission. We directly visualise how uniaxial stress drives a Lifshitz transition of the γ-band Fermi surface, pointing to the key role of strain-tuning its associated van Hove singularity to the Fermi level in mediating the peak in Tc. Our measurements provide stringent constraints for theoretical models of the strain-tuned electronic structure evolution of Sr2RuO4. More generally, our experimental approach opens the door to future studies of strain-tuned phase transitions not only using photoemission but also other experimental techniques where large pressure cells or piezoelectric-based devices may be difficult to implement.

AB - Pressure represents a clean tuning parameter for traversing the complex phase diagrams of interacting electron systems, and as such has proved of key importance in the study of quantum materials. Application of controlled uniaxial pressure has recently been shown to more than double the transition temperature of the unconventional superconductor Sr2RuO4, leading to a pronounced peak in Tc versus strain whose origin is still under active debate. Here we develop a simple and compact method to passively apply large uniaxial pressures in restricted sample environments, and utilise this to study the evolution of the electronic structure of Sr2RuO4 using angle-resolved photoemission. We directly visualise how uniaxial stress drives a Lifshitz transition of the γ-band Fermi surface, pointing to the key role of strain-tuning its associated van Hove singularity to the Fermi level in mediating the peak in Tc. Our measurements provide stringent constraints for theoretical models of the strain-tuned electronic structure evolution of Sr2RuO4. More generally, our experimental approach opens the door to future studies of strain-tuned phase transitions not only using photoemission but also other experimental techniques where large pressure cells or piezoelectric-based devices may be difficult to implement.

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