Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4

Davide Curcio; Charlotte E. Sanders; Alla Chikina; Henriette E. Lund; Marco Bianchi; Veronica Granata; Marco Cannavacciuolo; Giuseppe Cuono; Carmine Autieri; Filomena Forte; Guerino Avallone; Alfonso Romano; Mario Cuoco; Pavel Dudin; Jose Avila; Craig Polley; Thiagarajan Balasubramanian; Rosalba Fittipaldi; Antonio Vecchione; Philip Hofmann

doi:10.1103/PhysRevB.108.L161105

Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4

Davide Curcio, Charlotte E. Sanders, Alla Chikina, Henriette E. Lund, Marco Bianchi, Veronica Granata, Marco Cannavacciuolo, Giuseppe Cuono, Carmine Autieri, Filomena Forte, Guerino Avallone, Alfonso Romano, Mario Cuoco, Pavel Dudin, Jose Avila, Craig Polley, Thiagarajan Balasubramanian, Rosalba Fittipaldi, Antonio Vecchione, Philip Hofmann

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

Abstract

The electrical control of a material's conductivity is at the heart of modern electronics. Conventionally, this control is achieved by tuning the density of mobile charge carriers. A completely different approach is possible in Mott insulators such as Ca2RuO4, where an insulator-to-metal transition (IMT) can be induced by a weak electric field or current. While the driving force of the IMT is poorly understood, it has been thought to be a breakdown of the Mott state. Using in operando angle-resolved photoemission spectroscopy, we show that this is not the case: The current-induced conductivity is caused by the formation of in-gap states with only a minor reorganization of the Mott state. Electronic structure calculations show that these in-gap states form at the boundaries of structural domains that emerge during the IMT. At such boundaries, the overall gap is drastically reduced, even if the structural difference between the domains is small and the individual domains retain their Mott character. The inhomogeneity of the sample is thus key to understanding the IMT, as it leads to a nonequilibrium semimetallic state that forms at the interface of Mott domains.

Original language	English
Article number	L161105
Journal	Physical Review B
Volume	108
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.108.L161105
Publication status	Published - 2023 Oct

Subject classification (UKÄ)

Condensed Matter Physics

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10.1103/PhysRevB.108.L161105

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Curcio, D., Sanders, C. E., Chikina, A., Lund, H. E., Bianchi, M., Granata, V., Cannavacciuolo, M., Cuono, G., Autieri, C., Forte, F., Avallone, G., Romano, A., Cuoco, M., Dudin, P., Avila, J., Polley, C., Balasubramanian, T., Fittipaldi, R., Vecchione, A., & Hofmann, P. (2023). Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4. Physical Review B, 108(16), Article L161105. https://doi.org/10.1103/PhysRevB.108.L161105

@article{26e06c5d4ea14d68b7a75e154f4a982d,

title = "Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4",

abstract = "The electrical control of a material's conductivity is at the heart of modern electronics. Conventionally, this control is achieved by tuning the density of mobile charge carriers. A completely different approach is possible in Mott insulators such as Ca2RuO4, where an insulator-to-metal transition (IMT) can be induced by a weak electric field or current. While the driving force of the IMT is poorly understood, it has been thought to be a breakdown of the Mott state. Using in operando angle-resolved photoemission spectroscopy, we show that this is not the case: The current-induced conductivity is caused by the formation of in-gap states with only a minor reorganization of the Mott state. Electronic structure calculations show that these in-gap states form at the boundaries of structural domains that emerge during the IMT. At such boundaries, the overall gap is drastically reduced, even if the structural difference between the domains is small and the individual domains retain their Mott character. The inhomogeneity of the sample is thus key to understanding the IMT, as it leads to a nonequilibrium semimetallic state that forms at the interface of Mott domains.",

author = "Davide Curcio and Sanders, {Charlotte E.} and Alla Chikina and Lund, {Henriette E.} and Marco Bianchi and Veronica Granata and Marco Cannavacciuolo and Giuseppe Cuono and Carmine Autieri and Filomena Forte and Guerino Avallone and Alfonso Romano and Mario Cuoco and Pavel Dudin and Jose Avila and Craig Polley and Thiagarajan Balasubramanian and Rosalba Fittipaldi and Antonio Vecchione and Philip Hofmann",

year = "2023",

month = oct,

doi = "10.1103/PhysRevB.108.L161105",

language = "English",

volume = "108",

journal = "Physical Review B",

issn = "2469-9950",

publisher = "American Physical Society",

number = "16",

}

Curcio, D, Sanders, CE, Chikina, A, Lund, HE, Bianchi, M, Granata, V, Cannavacciuolo, M, Cuono, G, Autieri, C, Forte, F, Avallone, G, Romano, A, Cuoco, M, Dudin, P, Avila, J, Polley, C, Balasubramanian, T, Fittipaldi, R, Vecchione, A & Hofmann, P 2023, 'Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4', Physical Review B, vol. 108, no. 16, L161105. https://doi.org/10.1103/PhysRevB.108.L161105

TY - JOUR

T1 - Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4

AU - Curcio, Davide

AU - Sanders, Charlotte E.

AU - Chikina, Alla

AU - Lund, Henriette E.

AU - Bianchi, Marco

AU - Granata, Veronica

AU - Cannavacciuolo, Marco

AU - Cuono, Giuseppe

AU - Autieri, Carmine

AU - Forte, Filomena

AU - Avallone, Guerino

AU - Romano, Alfonso

AU - Cuoco, Mario

AU - Dudin, Pavel

AU - Avila, Jose

AU - Polley, Craig

AU - Balasubramanian, Thiagarajan

AU - Fittipaldi, Rosalba

AU - Vecchione, Antonio

AU - Hofmann, Philip

PY - 2023/10

Y1 - 2023/10

N2 - The electrical control of a material's conductivity is at the heart of modern electronics. Conventionally, this control is achieved by tuning the density of mobile charge carriers. A completely different approach is possible in Mott insulators such as Ca2RuO4, where an insulator-to-metal transition (IMT) can be induced by a weak electric field or current. While the driving force of the IMT is poorly understood, it has been thought to be a breakdown of the Mott state. Using in operando angle-resolved photoemission spectroscopy, we show that this is not the case: The current-induced conductivity is caused by the formation of in-gap states with only a minor reorganization of the Mott state. Electronic structure calculations show that these in-gap states form at the boundaries of structural domains that emerge during the IMT. At such boundaries, the overall gap is drastically reduced, even if the structural difference between the domains is small and the individual domains retain their Mott character. The inhomogeneity of the sample is thus key to understanding the IMT, as it leads to a nonequilibrium semimetallic state that forms at the interface of Mott domains.

AB - The electrical control of a material's conductivity is at the heart of modern electronics. Conventionally, this control is achieved by tuning the density of mobile charge carriers. A completely different approach is possible in Mott insulators such as Ca2RuO4, where an insulator-to-metal transition (IMT) can be induced by a weak electric field or current. While the driving force of the IMT is poorly understood, it has been thought to be a breakdown of the Mott state. Using in operando angle-resolved photoemission spectroscopy, we show that this is not the case: The current-induced conductivity is caused by the formation of in-gap states with only a minor reorganization of the Mott state. Electronic structure calculations show that these in-gap states form at the boundaries of structural domains that emerge during the IMT. At such boundaries, the overall gap is drastically reduced, even if the structural difference between the domains is small and the individual domains retain their Mott character. The inhomogeneity of the sample is thus key to understanding the IMT, as it leads to a nonequilibrium semimetallic state that forms at the interface of Mott domains.

U2 - 10.1103/PhysRevB.108.L161105

DO - 10.1103/PhysRevB.108.L161105

M3 - Article

AN - SCOPUS:85175853676

SN - 2469-9950

VL - 108

JO - Physical Review B

JF - Physical Review B

IS - 16

M1 - L161105

ER -

Current-driven insulator-to-metal transition without Mott breakdown in Ca2RuO4

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