Basic aspects of the metal–insulator transition in vanadium dioxide VO 2 : a critical review

IF 1.3 4区 物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS Comptes Rendus Physique Pub Date : 2021-06-11 DOI:10.5802/CRPHYS.74
J. Pouget
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引用次数: 16

Abstract

Vanadium dioxide exhibits a first order metal to insulator transition (MIT) at 340 K (TMI) from a rutile (R) structure to a monoclinic (M1) structure. The mechanism of this transition interpreted as due either to a Peierls instability or to a Mott–Hubbard instability is controversial since half a century. However, in the last twenty years the study of chemical and physical properties of VO2 and of its alloys, benefits of a renewed interest due to possible applications coming from the realization of devices made of thin films. We describe in this review the structural, electronic and magnetic properties of the different metallic (R) and insulating (M1, T, M2) phases of VO2, of its solid solutions and under constraint. We present in a synthetic manner the various phase diagrams and their symmetry analysis. This work allows us to revisit older interpretation and to emphasize in particular the combined role of electron–electron interactions in the various phase of VO2 and of structural fluctuations in the MIT mechanism. In this framework we show that the phase transition is surprisingly announced by anisotropic one-dimensional (1D) structural fluctuations revealing chain like correlations between the V due to an incipient instability of the rutile structure. This leads to an unexpected critical dynamics of the order–disorder (or relaxation) type. We describe how the two-dimensional (2D) coupling between these 1D fluctuations, locally forming uniform V4+ zig-zag chains and V–V pairs, stabilizes the M2 and M1 insulating phases. These phases exhibit a 1D electronic anisotropy where substantial electron–electron correlations conduct to a spin–charge decoupling. The spin-Peierls ground state of M1 is analyzed via a mechanism of dimerization, in the T phase, of the spin 1/2 V 4+ zigzag Heisenberg chains formed in the M2 phase. This review summarizes in a critical manner the main results of the large literature on fundamental aspects of the MIT of VO2. It is completed by unpublished old results. Interpretations are also placed in a large conceptual frame which is also relevant to interpret physical properties of other classes of materials. Résumé. Le dioxyde de vanadium présente une transition métal–isolant (TMI) du premier ordre à 340 K (=TMI) d’une structure rutile (R) à une structure monoclinique (M1). Le mécanisme de cette transition interprétée comme étant due soit à une instabilité de Peierls soit à une instabilité de Mott–Hubbard reste très controversé depuis près d’un demi-siècle. Cependant depuis une vingtaine d’années l’étude des propriétés chimiques et physiques de VO2 et de ses alliages suscite un renouveau d’intérêt par la possibilité d’applications provenant de l’obtention de dispositifs s’appuyant sur la réalisation de films minces. Nous décrivons dans cette revue les propriétés structurales, électroniques et magnétiques des différentes phases métallique ISSN (electronic) : 1878-1535 https://comptes-rendus.academie-sciences.fr/physique/
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二氧化钒VO 2中金属-绝缘体转变的基本方面:综述
在340 K (TMI)温度下,二氧化钒表现出从金红石(R)结构到单斜晶(M1)结构的一阶金属到绝缘体转变(MIT)。这种转变的机制被解释为由于佩尔斯不稳定性或莫特-哈伯德不稳定性,半个世纪以来一直存在争议。然而,在过去的二十年中,对氧化钨及其合金的化学和物理性质的研究,由于可能的应用来自于薄膜器件的实现而重新引起了人们的兴趣。本文描述了VO2的不同金属相(R)和绝缘相(M1, T, M2)、固溶体和约束条件下的结构、电子和磁性能。我们以综合的方式给出了各种相图及其对称性分析。这项工作使我们能够重新审视旧的解释,并特别强调电子-电子相互作用在VO2的各个阶段和MIT机制中的结构波动的综合作用。在这个框架中,我们证明了相变是由各向异性的一维(1D)结构波动出人意料地宣布的,揭示了由于金红石结构的早期不稳定性而导致的V之间的链状相关性。这导致了一种意想不到的有序-无序(或松弛)类型的临界动态。我们描述了这些一维波动之间的二维(2D)耦合如何在局部形成均匀的V4+之字形链和V-V对,从而稳定M2和M1绝缘相。这些相表现出一维电子各向异性,其中大量的电子-电子相关导致自旋-电荷去耦。通过M2相中形成的自旋1/ 2v4 +之字形海森堡链在T相中二聚化的机制,分析了M1的自旋-佩尔斯基态。这篇综述以一种批判性的方式总结了关于VO2的MIT基本方面的大量文献的主要结果。它是由未发表的旧结果完成的。解释也被置于一个大的概念框架中,这也与解释其他类别材料的物理性质有关。的简历。二氧化钒的单晶过渡单晶隔离(TMI) du premier order: 340k (=TMI),单晶结构金红石(R),单晶结构单晶(M1)。Le macimcanisme de cette transition interpracimetacme comcomtant due soit une instability . de peerls soit une instability . de mot - hubbard restere tris有争议的suispris d 'un demi- si。Cependant从一个vingtaine d 'annees我des proprietes chimiques等最大的体格不吸烟者ses alliages suscite联合国renouveau有票面拉一d 'applications provenant de l 'obtention de dispositifs年代'appuyant在洛杉矶认识电影切碎。Nous dsamrivons dans cette revue les propriacematsames strucales,电子的samriques和不同的samriques des different samrites phases .(电子版):1878-1535 https://comptes-rendus.academie-sciences.fr/physique/
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来源期刊
Comptes Rendus Physique
Comptes Rendus Physique 物理-天文与天体物理
CiteScore
2.80
自引率
0.00%
发文量
13
审稿时长
17.2 weeks
期刊介绍: The Comptes Rendus - Physique are an open acess and peer-reviewed electronic scientific journal publishing original research article. It is one of seven journals published by the Académie des sciences. Its objective is to enable researchers to quickly share their work with the international scientific community. The Comptes Rendus - Physique also publish journal articles, thematic issues and articles on the history of the Académie des sciences and its current scientific activity. From 2020 onwards, the journal''s policy is based on a diamond open access model: no fees are charged to authors to publish or to readers to access articles. Thus, articles are accessible immediately, free of charge and permanently after publication. The Comptes Rendus - Physique (8 issues per year) cover all fields of physics and astrophysics and propose dossiers. Thanks to this formula, readers of physics and astrophysics will find, in each issue, the presentation of a subject in particularly rapid development. The authors are chosen from among the most active researchers in the field and each file is coordinated by a guest editor, ensuring that the most recent and significant results are taken into account. In order to preserve the historical purpose of the Comptes Rendus, these issues also leave room for the usual notes and clarifications. The articles are written mainly in English.
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