Giant topological Hall effect in correlated oxide thin films

Lorenzo Vistoli; Wenbo Wang; Anke Sander; Qiuxiang Zhu; Blai Casals; Rafael Cichelero; Agnès Barthélémy; Stéphane Fusil; Gervasi Herranz; Sergio Valencia; Radu Abrudan; Eugen Weschke; Kazuki Nakazawa; Hiroshi Kohno; Jacobo Santamaria; Weida Wu; Vincent Garcia; Manuel Bibes

doi:10.1038/s41567-018-0307-5

Giant topological Hall effect in correlated oxide thin films

Lorenzo Vistoli
, Wenbo Wang
, Anke Sander
, Qiuxiang Zhu
, Blai Casals
, Rafael Cichelero
, Agnès Barthélémy
, Stéphane Fusil
, Gervasi Herranz
, Sergio Valencia
, Radu Abrudan
, Eugen Weschke
, Kazuki Nakazawa
, Hiroshi Kohno
, Jacobo Santamaria
, Weida Wu
, Vincent Garcia
, Manuel Bibes^*

^*此作品的通讯作者

Unité Mixte de Physique CNRS/Thales
Rutgers - The State University of New Jersey, New Brunswick
Autonomous University of Barcelona
Universite Paris-Saclay
Helmholtz Centre Berlin for Materials and Energy
The University of Osaka
Nagoya University
Complutense University

科研成果: 期刊稿件 › 文章 › 同行评审

147 引用（Scopus）

摘要

Strong electronic correlations can produce remarkable phenomena such as metal–insulator transitions and greatly enhance superconductivity, thermoelectricity or optical nonlinearity. In correlated systems, spatially varying charge textures also amplify magnetoelectric effects or electroresistance in mesostructures. However, how spatially varying spin textures may influence electron transport in the presence of correlations remains unclear. Here we demonstrate a very large topological Hall effect (THE) in thin films of a lightly electron-doped charge-transfer insulator, (Ca,Ce)MnO ₃ . Magnetic force microscopy reveals the presence of magnetic bubbles, whose density as a function of magnetic field peaks near the THE maximum. The THE critically depends on carrier concentration and diverges at low doping, near the metal–insulator transition. We discuss the strong amplification of the THE by correlation effects and give perspectives for its non-volatile control by electric fields.

源语言	英语
页（从-至）	67-72
页数	6
期刊	Nature Physics
卷	15
期	1
DOI	https://doi.org/10.1038/s41567-018-0307-5
出版状态	已出版 - 1 1月 2019
已对外发布	是

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abstract = " Strong electronic correlations can produce remarkable phenomena such as metal–insulator transitions and greatly enhance superconductivity, thermoelectricity or optical nonlinearity. In correlated systems, spatially varying charge textures also amplify magnetoelectric effects or electroresistance in mesostructures. However, how spatially varying spin textures may influence electron transport in the presence of correlations remains unclear. Here we demonstrate a very large topological Hall effect (THE) in thin films of a lightly electron-doped charge-transfer insulator, (Ca,Ce)MnO 3 . Magnetic force microscopy reveals the presence of magnetic bubbles, whose density as a function of magnetic field peaks near the THE maximum. The THE critically depends on carrier concentration and diverges at low doping, near the metal–insulator transition. We discuss the strong amplification of the THE by correlation effects and give perspectives for its non-volatile control by electric fields.",

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T1 - Giant topological Hall effect in correlated oxide thin films

AU - Vistoli, Lorenzo

AU - Wang, Wenbo

AU - Sander, Anke

AU - Zhu, Qiuxiang

AU - Casals, Blai

AU - Cichelero, Rafael

AU - Barthélémy, Agnès

AU - Fusil, Stéphane

AU - Herranz, Gervasi

AU - Valencia, Sergio

AU - Abrudan, Radu

AU - Weschke, Eugen

AU - Nakazawa, Kazuki

AU - Kohno, Hiroshi

AU - Santamaria, Jacobo

AU - Wu, Weida

AU - Garcia, Vincent

AU - Bibes, Manuel

PY - 2019/1/1

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N2 - Strong electronic correlations can produce remarkable phenomena such as metal–insulator transitions and greatly enhance superconductivity, thermoelectricity or optical nonlinearity. In correlated systems, spatially varying charge textures also amplify magnetoelectric effects or electroresistance in mesostructures. However, how spatially varying spin textures may influence electron transport in the presence of correlations remains unclear. Here we demonstrate a very large topological Hall effect (THE) in thin films of a lightly electron-doped charge-transfer insulator, (Ca,Ce)MnO 3 . Magnetic force microscopy reveals the presence of magnetic bubbles, whose density as a function of magnetic field peaks near the THE maximum. The THE critically depends on carrier concentration and diverges at low doping, near the metal–insulator transition. We discuss the strong amplification of the THE by correlation effects and give perspectives for its non-volatile control by electric fields.

AB - Strong electronic correlations can produce remarkable phenomena such as metal–insulator transitions and greatly enhance superconductivity, thermoelectricity or optical nonlinearity. In correlated systems, spatially varying charge textures also amplify magnetoelectric effects or electroresistance in mesostructures. However, how spatially varying spin textures may influence electron transport in the presence of correlations remains unclear. Here we demonstrate a very large topological Hall effect (THE) in thin films of a lightly electron-doped charge-transfer insulator, (Ca,Ce)MnO 3 . Magnetic force microscopy reveals the presence of magnetic bubbles, whose density as a function of magnetic field peaks near the THE maximum. The THE critically depends on carrier concentration and diverges at low doping, near the metal–insulator transition. We discuss the strong amplification of the THE by correlation effects and give perspectives for its non-volatile control by electric fields.

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VL - 15

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Giant topological Hall effect in correlated oxide thin films

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