A spin-orbit playground: Surfaces and interfaces of transition metal oxides

S. Gariglio; A. D. Caviglia; J. M. Triscone; M. Gabay

doi:10.1088/1361-6633/aad6ab

A spin-orbit playground: Surfaces and interfaces of transition metal oxides

S. Gariglio, A. D. Caviglia, J. M. Triscone, M. Gabay

QN/Caviglia Lab

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

30 Citations (Scopus)

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Abstract

Within the last twenty years, the status of the spinorbit interaction has evolved from that of a simple atomic contribution to a key effect that modifies the electronic band structure of materials. It is regarded as one of the basic ingredients for spintronics, locking together charge and spin degrees of freedom and recently it is instrumental in promoting a new class of compounds, the topological insulators. In this review, we present the current status of the research on the spinorbit coupling in transition metal oxides, discussing the case of two semiconducting compounds, SrTiO₃and KTaO₃, and the properties of surface and interfaces based on these. We conclude with the investigation of topological effects predicted to occur in different complex oxides.

Original language	English
Article number	012501
Number of pages	12
Journal	Reports on Progress in Physics
Volume	82
Issue number	1
DOIs	https://doi.org/10.1088/1361-6633/aad6ab
Publication status	Published - 2019

Keywords

2DEG
spinorbit coupling
superconductivity
topological states
transition-metal oxides

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10.1088/1361-6633/aad6ab

spin-orbitAccepted author manuscript, 2.51 MB

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title = "A spin-orbit playground: Surfaces and interfaces of transition metal oxides",

abstract = "Within the last twenty years, the status of the spinorbit interaction has evolved from that of a simple atomic contribution to a key effect that modifies the electronic band structure of materials. It is regarded as one of the basic ingredients for spintronics, locking together charge and spin degrees of freedom and recently it is instrumental in promoting a new class of compounds, the topological insulators. In this review, we present the current status of the research on the spinorbit coupling in transition metal oxides, discussing the case of two semiconducting compounds, SrTiO3and KTaO3, and the properties of surface and interfaces based on these. We conclude with the investigation of topological effects predicted to occur in different complex oxides.",

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AU - Gariglio, S.

AU - Caviglia, A. D.

AU - Triscone, J. M.

AU - Gabay, M.

PY - 2019

Y1 - 2019

N2 - Within the last twenty years, the status of the spinorbit interaction has evolved from that of a simple atomic contribution to a key effect that modifies the electronic band structure of materials. It is regarded as one of the basic ingredients for spintronics, locking together charge and spin degrees of freedom and recently it is instrumental in promoting a new class of compounds, the topological insulators. In this review, we present the current status of the research on the spinorbit coupling in transition metal oxides, discussing the case of two semiconducting compounds, SrTiO3and KTaO3, and the properties of surface and interfaces based on these. We conclude with the investigation of topological effects predicted to occur in different complex oxides.

AB - Within the last twenty years, the status of the spinorbit interaction has evolved from that of a simple atomic contribution to a key effect that modifies the electronic band structure of materials. It is regarded as one of the basic ingredients for spintronics, locking together charge and spin degrees of freedom and recently it is instrumental in promoting a new class of compounds, the topological insulators. In this review, we present the current status of the research on the spinorbit coupling in transition metal oxides, discussing the case of two semiconducting compounds, SrTiO3and KTaO3, and the properties of surface and interfaces based on these. We conclude with the investigation of topological effects predicted to occur in different complex oxides.

KW - 2DEG

KW - spinorbit coupling

KW - superconductivity

KW - topological states

KW - transition-metal oxides

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DO - 10.1088/1361-6633/aad6ab

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JO - Reports on Progress in Physics

JF - Reports on Progress in Physics

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A spin-orbit playground: Surfaces and interfaces of transition metal oxides

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