Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression

Edgar Abarca Morales; Gesa R. Siemann; Andela Zivanovic; Philip A.E. Murgatroyd; Igor Marković; Brendan Edwards; Chris A. Hooley; Dmitry A. Sokolov; Naoki Kikugawa; Cephise Cacho; Matthew D. Watson; Timur K. Kim; Clifford W. Hicks; Andrew P. MacKenzie; Phil D.C. King

doi:10.1103/PhysRevLett.130.096401

Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression

Edgar Abarca Morales
, Gesa R. Siemann
, Andela Zivanovic
, Philip A.E. Murgatroyd
, Igor Marković
, Brendan Edwards
, Chris A. Hooley
, Dmitry A. Sokolov
, Naoki Kikugawa
, Cephise Cacho
, Matthew D. Watson
, Timur K. Kim
, Clifford W. Hicks
, Andrew P. MacKenzie
, Phil D.C. King

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

14 Citations (Scopus)

Abstract

We report the evolution of the electronic structure at the surface of the layered perovskite Sr2RuO4 under large in-plane uniaxial compression, leading to anisotropic B1g strains of µxx- µyy=-0.9±0.1%. From angle-resolved photoemission, we show how this drives a sequence of Lifshitz transitions, reshaping the low-energy electronic structure and the rich spectrum of van Hove singularities that the surface layer of Sr2RuO4 hosts. From comparison to tight-binding modeling, we find that the strain is accommodated predominantly by bond-length changes rather than modifications of octahedral tilt and rotation angles. Our study sheds new light on the nature of structural distortions at oxide surfaces, and how targeted control of these can be used to tune density of state singularities to the Fermi level, in turn paving the way to the possible realization of rich collective states at the Sr2RuO4 surface.

Original language	English
Article number	096401
Number of pages	8
Journal	Physical Review Letters
Volume	130
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.130.096401
Publication status	Published - 3 Mar 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2023 American Physical Society.

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.130.096401

Cite this

Abarca Morales, E., Siemann, G. R., Zivanovic, A., Murgatroyd, P. A. E., Marković, I., Edwards, B., Hooley, C. A., Sokolov, D. A., Kikugawa, N., Cacho, C., Watson, M. D., Kim, T. K., Hicks, C. W., MacKenzie, A. P., & King, P. D. C. (2023). Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression. Physical Review Letters, 130(9), Article 096401. https://doi.org/10.1103/PhysRevLett.130.096401

Abarca Morales, E, Siemann, GR, Zivanovic, A, Murgatroyd, PAE, Marković, I, Edwards, B, Hooley, CA, Sokolov, DA, Kikugawa, N, Cacho, C, Watson, MD, Kim, TK, Hicks, CW, MacKenzie, AP & King, PDC 2023, 'Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression', Physical Review Letters, vol. 130, no. 9, 096401. https://doi.org/10.1103/PhysRevLett.130.096401

@article{1335e802d0b643d58be80f13d1c5a361,

title = "Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression",

abstract = "We report the evolution of the electronic structure at the surface of the layered perovskite Sr2RuO4 under large in-plane uniaxial compression, leading to anisotropic B1g strains of µxx- µyy=-0.9±0.1\%. From angle-resolved photoemission, we show how this drives a sequence of Lifshitz transitions, reshaping the low-energy electronic structure and the rich spectrum of van Hove singularities that the surface layer of Sr2RuO4 hosts. From comparison to tight-binding modeling, we find that the strain is accommodated predominantly by bond-length changes rather than modifications of octahedral tilt and rotation angles. Our study sheds new light on the nature of structural distortions at oxide surfaces, and how targeted control of these can be used to tune density of state singularities to the Fermi level, in turn paving the way to the possible realization of rich collective states at the Sr2RuO4 surface.",

author = "\{Abarca Morales\}, Edgar and Siemann, \{Gesa R.\} and Andela Zivanovic and Murgatroyd, \{Philip A.E.\} and Igor Markovi{\'c} and Brendan Edwards and Hooley, \{Chris A.\} and Sokolov, \{Dmitry A.\} and Naoki Kikugawa and Cephise Cacho and Watson, \{Matthew D.\} and Kim, \{Timur K.\} and Hicks, \{Clifford W.\} and MacKenzie, \{Andrew P.\} and King, \{Phil D.C.\}",

note = "Publisher Copyright: {\textcopyright} 2023 American Physical Society. ",

year = "2023",

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doi = "10.1103/PhysRevLett.130.096401",

language = "English",

volume = "130",

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AU - Abarca Morales, Edgar

AU - Siemann, Gesa R.

AU - Zivanovic, Andela

AU - Murgatroyd, Philip A.E.

AU - Marković, Igor

AU - Edwards, Brendan

AU - Hooley, Chris A.

AU - Sokolov, Dmitry A.

AU - Kikugawa, Naoki

AU - Cacho, Cephise

AU - Watson, Matthew D.

AU - Kim, Timur K.

AU - Hicks, Clifford W.

AU - MacKenzie, Andrew P.

AU - King, Phil D.C.

PY - 2023/3/3

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N2 - We report the evolution of the electronic structure at the surface of the layered perovskite Sr2RuO4 under large in-plane uniaxial compression, leading to anisotropic B1g strains of µxx- µyy=-0.9±0.1%. From angle-resolved photoemission, we show how this drives a sequence of Lifshitz transitions, reshaping the low-energy electronic structure and the rich spectrum of van Hove singularities that the surface layer of Sr2RuO4 hosts. From comparison to tight-binding modeling, we find that the strain is accommodated predominantly by bond-length changes rather than modifications of octahedral tilt and rotation angles. Our study sheds new light on the nature of structural distortions at oxide surfaces, and how targeted control of these can be used to tune density of state singularities to the Fermi level, in turn paving the way to the possible realization of rich collective states at the Sr2RuO4 surface.

AB - We report the evolution of the electronic structure at the surface of the layered perovskite Sr2RuO4 under large in-plane uniaxial compression, leading to anisotropic B1g strains of µxx- µyy=-0.9±0.1%. From angle-resolved photoemission, we show how this drives a sequence of Lifshitz transitions, reshaping the low-energy electronic structure and the rich spectrum of van Hove singularities that the surface layer of Sr2RuO4 hosts. From comparison to tight-binding modeling, we find that the strain is accommodated predominantly by bond-length changes rather than modifications of octahedral tilt and rotation angles. Our study sheds new light on the nature of structural distortions at oxide surfaces, and how targeted control of these can be used to tune density of state singularities to the Fermi level, in turn paving the way to the possible realization of rich collective states at the Sr2RuO4 surface.

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JO - Physical Review Letters

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Hierarchy of Lifshitz Transitions in the Surface Electronic Structure of Sr2RuO4 under Uniaxial Compression

Abstract

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