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Pouget, Jean‐Paul; Launois, H.; D’Haenens, J. P.; Merenda, P.; Rice, T. M.

doi:10.1103/physrevlett.35.873

Cited by 297 publications

(304 citation statements)

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“…1. Under hole-doping [5] or stress [6], another monoclinic phase (M 2 ) shows up with antiferromagnetically (AFM) coupled V chains (denoted as V 1 in Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

VO2: Orbital competition, magnetism, and phase stability

et al. 2012

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The relative phase stability of VO2 is one of the most fundamental issues concerning the metalinsulator transition in this material but has so far largely unexplored theoretically. We investigate the relative stability of various phases of VO2 using different levels of energy functionals within density functional theory (DFT). It is found that straightforward applications of several popular energy functionals, including the Heyd-Scuseria-Ernzerhof (HSE) hybrid functional, result in a wrong prediction for the ground state of VO2. In particular, although the HSE and DFT+U methods are able to produce a band gap in the M1 phase, they strongly favor the formation of local magnetic moments, a result that clearly disagrees with experiments. We also examine the effect of the occupation and the redistribution of the d derived t2g (i.e., dxz, dyz and d x 2 −y 2 ) orbitals of V atoms on the calculated relative phase stability of VO2. We find that a small change in d-occupation can result in a drastically different theoretical prediction. With the introduction of an orbital-dependent potential, a complete separation between the d x 2 −y 2 derived valence band and dxz and dyz derived conduction bands in the M1 phase is achieved, resulting in a slight redistribution of the d occupation and a more faithful account of the polarization of the t2g orbitals. This slight rearrangement of the d occupation also leads to a relative phase stability of VO2 (including structural and magnetic phases) that agrees well with experiment.

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“…1. Under hole-doping [5] or stress [6], another monoclinic phase (M 2 ) shows up with antiferromagnetically (AFM) coupled V chains (denoted as V 1 in Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

VO2: Orbital competition, magnetism, and phase stability

et al. 2012

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“…However, a precise quantitative understanding of how this scheme is realized-in particular the roles of electronic correlations and the structural instability in the MIT-remains a matter of debate. [15][16][17][18] A complete understanding of this correlated system is necessary to predict and control the emergent properties as a function of external parameters.…”

Section: Introductionmentioning

confidence: 99%

Modification of electronic structure in compressively strained vanadium dioxide films

Huffman

Hollingshad

et al. 2015

Phys. Rev. B

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Vanadium dioxide (VO 2 ) undergoes a phase transition between an insulating monoclinic (M 1 ) phase and a conducting rutile phase. Like other correlated electron systems, the properties of VO 2 can be extremely sensitive to small changes in external parameters such as strain. In this work, we investigate a compressively strained VO 2 film grown on [001] quartz substrate in which the phase transition temperature (T c ) has been depressed to 325K from the bulk value of 340K. Infrared and optical spectroscopy reveals that the lattice dynamics of this strained film are very similar to unstrained VO 2 . However, some of the electronic inter-band transitions of the strained VO 2 film are significantly shifted in energy from those in unstrained VO 2 . That the lattice dynamics remain largely unchanged, while the T c and some of the electronic inter-band transitions differ substantially from the bulk values highlight the role of electronic correlations in driving this metal-insulator phase transition.

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“…The MCM phase as evidence of the Mott transition clarifies the controversial problem. MCM differs from Pouget et al's M 2 Mott-Hubbard insulator phase [5,6]. We consider that T can be the paramagnetic Mott insulator with the equally spaced chain structure because T and MCM have the same structure.…”

mentioning

confidence: 99%

“…Actually, even in this case, the MIT was not simultaneous with the SPT in our work [7]. When voltage is applied to a VO 2 -based device [7], the MIT occurs between T (monoclinic semiconductor phase, transient triclinic) [5,6] and MCM (monoclinic and correlated metal) phase with the increase of σ. The SPT happens between MCM and R (rutile tetragonal metal phase) (SPT instability, red-dash line in Fig.…”

mentioning

confidence: 99%

“…The reason why the measured conductivity with doping is continuous is that the magnitude of a local metal conductivity after the MIT is very small because the local area is within about 3nm [1]. Furthermore, the Mott MIT [5][6][7] and the Peierls MIT with the SPT [8,9] have been controversial even in VO 2 as a representative Mott insulator. This is due to ambiguity of relation between MIT and SPT.…”

mentioning

confidence: 99%

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Hole-driven MIT theory, Mott transition in VO2, MoBRiK device

Kim

Lee

et al. 2007

Physica C: Superconductivity

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For inhomogeneous high-Tc superconductors, hole-driven metal-insulator transition (MIT) theory explains that the gradual increase of conductivity with increasing hole doping is due to inhomogeneity with the local Mott system undergoing the first-order MIT and the local non-Mott system. For VO2, a monoclinic and correlated metal (MCM) phase showing the linear characteristic as evidence of the Mott MIT is newly observed by applying electric field and temperature. The structural phase transition occurs between MCM and Rutile metal phases. Devices using the MIT are named MoBRiK.It has been generally accepted that conductivity,σ, and T c for inhomogeneous high-T c superconductors [1] as strongly correlated systems gradually increase with doped hole density in a Mott insulator from under-doping to critical doping [2], although a first-order transition near the Mott insulator had been theoretically suggested [3]. These phenomena seemed to be explained by the Mott-Hubbard (MH) continuous metal-insulator transition (MIT) theory. However, since the MH theory was established for homogeneous system, the theory does not explain the phenomena in inhomogeneous system. The first-order Mott MIT without the structural phase transition (SPT) has not clearly been proved. This paper briefly describes important ideas and physical meanings of the hole-driven MIT theory (extended Brinkman-Rice (BR) picture [4]) named by a reviewer in ref. 7 and explains the above phenomena. An experimental observation is also presented to clarify the Mott MIT.Metal has the electronic structure of one electron per atom in real space, i.e. half filling, which indicates that δq= (q i -q j )=0 where q i and q j are charge quantities at i and j nearest neighbor sites, respectively [4]; there is no charge density wave. The BR picture explains physical properties of a strongly correlated metal, which was developed when n = l for a homogeneous system with one electron per atom, where n is the number of electrons in the Mott system with the electronic structure of metal ( Fig. 1(a) left) and l is the number of lattices in the measurement region [3]. The Mott insulator becomes metal via MIT.When n

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Electron Localization Induced by Uniaxial Stress in Pure VO2

Cited by 297 publications

References 9 publications

VO2: Orbital competition, magnetism, and phase stability

VO2: Orbital competition, magnetism, and phase stability

Modification of electronic structure in compressively strained vanadium dioxide films

Hole-driven MIT theory, Mott transition in VO2, MoBRiK device

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