Electric Field Control of Jahn-Teller Distortions in Bulk Perovskites

Varignon, Julien; Bristowe, Nicholas C.; Ghosez, Philippe

doi:10.1103/physrevlett.116.057602

Cited by 46 publications

(57 citation statements)

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“…1(a), we first observe that with average valence +3.5, the vanadium ions are expected to disproportionate to V 3+ and V 4+ . Each valence state drives a corresponding Jahn-Teller distortion of its coordinating oxygen octahedron [25,26]. As shown in Fig.…”

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confidence: 99%

Charge-Order-Induced Ferroelectricity inLaVO3/SrVO3Superlattices

2017

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The structure and properties of the 1:1 superlattice of LaVO3 and SrVO3 are investigated with a firstprinciples density-functional-theory-plus-U (DFT+U ) method. The lowest energy states are antiferromagnetic charge-ordered Mott-insulating phases. In one of these insulating phases, layered charge ordering combines with the layered cation ordering to produce a polar structure with nonzero spontaneous polarization normal to the interfaces. This polarization is produced by electron transfer between the V 3+ and V 4+ layers, and is comparable to that of conventional ferroelectrics. The energy of this polar state relative to the nonpolar ground state is only 3 meV per vanadium. Under tensile strain, this energy difference can be further reduced, suggesting that the polar phase can be induced by applied electric field, yielding an antiferroelectric double-hysteresis loop. If the system does not switch back to the nonpolar state on removal of the field, a ferroelectric-type hysteresis loop could be observed. PACS numbers: 73.21.Cd, 75.25.Dk, 77.55.Px The investigation of novel mechanisms for ferroelectricity has attracted much interest in recent years, especially in the search for ferroelectrics with properties, such as ferromagnetism, that are contraindicated by the mechanism driving ferroelectricity in the prototypical perovskite titanates [1]. One approach, proposed by Khomskii [2,3] is to combine two symmetry-breaking orderings, neither of which separately lift inversion symmetry, to generate a switchable polar structure [4]. The specific orderings discussed by Khomskii are sitecentered charge ordering and bond-centered charge ordering. Ferroelectricity and multiferroelectricity induced by charge order have been proposed and reported in various magnetites, manganates, and charge transfer organic salts [2,3,5]. In some of these materials, the polarization is dominated by the electron transfer producing the charge order rather than by ionic displacements, leading to the term "electronic ferroelectricity." [6][7][8] In perovskite transition metal (TM) oxide (ABO 3 ) n (A BO 3 ) m (001) superlattices, the layered cation ordering lowers the symmetry from cubic to tetragonal and breaks up-down symmetry across BO 2 layers. Control of the TM d-orbital occupancy through choice of A cations and layer thicknesses to obtain a mixed valence leads to charge disproportionation and long-range charge ordering [9-12]. As we will discuss further below, layered charge ordering breaks the up-down symmetry across the AO and A O layers. Thus, the combination of these two symmetry-breaking orderings (TM site-centered charge ordering and layered cation ordering) can generate a switchable polar structure with polarization normal to the layers.A 1:1 superlattice composed of LaVO 3 and SrVO 3 is a promising candidate for this type of charge-order-induced ferroelectricity. The low temperature phases of orthorhombic LaVO 3 and cubic SrVO 3 are antiferromagnetic Mottinsulating and correlated metallic, respectively [9,[13][14][15]. When they f...

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Charge-Order-Induced Ferroelectricity inLaVO3/SrVO3Superlattices

2017

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“…Examples of these two latter quantities are two different oxygen octahedral tiltings, [1][2][3][4][5][6][7] one oxygen octahedral tiling and one antipolar motion, 8 one Jahn-Teller mode and one antiferrodistortive (or antipolar) distortion, 9,10 or even two pseudo-Jahn-Teller motions. 11 Note also that trilinear energetic couplings do not restrain themselves to polar materials since they can also arise in compounds possessing antipolar cation distortions via their couplings with antiphase and inphase octahedral tiltings.…”

Section: Introductionmentioning

confidence: 99%

Dynamics of antipolar distortions

2017

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Materials possessing antipolar cation motions are currently receiving a lot of attention because they are fundamentally intriguing while being technologically promising. Most studies devoted to these complex materials have focused on their static properties or on their zone-center phonons. As a result, some important dynamics of antipolar cation distortions, such as the temperature behavior of their phonon frequencies, have been much less investigated, despite the possibility to exhibit unusual features. Here, we report the results and analysis of atomistic simulations revealing and explaining such dynamics for BiFeO 3 bulks being subject to hydrostatic pressure. It is first predicted that cooling such material yields the following phase transition sequence: the cubic paraelectric Pm3m state at high temperature, followed by an intermediate phase possessing long-range-ordered in-phase oxygen octahedral tiltings, and then the Pnma state that is known to possess antipolar cation motions in addition to in-phase and antiphase oxygen octahedral tiltings. Antipolar cation modes are found to all have high phonon frequencies that are independent of temperature in the paraelectric phase. On the other hand and in addition to antipolar cation modes increasing in number, some phonons possessing antipolar cation character are rather soft in the intermediate and Pnma states. Analysis of our data combined with the development of a simple model reveals that such features originate from a dynamical mixing between pure antipolar cation phonons and fluctuations of oxygen octahedral tiltings, as a result of a specific trilinear energetic coupling. The developed model can also be easily applied to predict dynamics of antipolar cation motions for other possible structural paths bringing Pm3m to Pnma states.

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“…It is rather the so-called K 3 mode, which consists of a tilt of the oxygen bipyramid and buckling of the R layers, and which generates a polarization via a 3 3 Q P K energetic coupling [23] (interestingly, in these hexagonal systems the magnitude of the polarization increases with hydrostatic pressure, [22,39] which contrasts with the present behavior shown in Figure 2b). Furthermore, some recent computational works also predict that polarization can couple with JT distortions, [17,18] but in such cases the polarization is the primary order parameter and couples with the JT modes via anharmonic trilinear terms. Such a trilinear couplings involve, in addition to the polarization and JT distortion, a third mode (typically, a tilting of the oxygen octahedra, or some antipolar motions); this is in stark contrast with our present case, where the key coupling only involves two modes, X 2 and 2 Γ − .…”

Section: Coupling Energiesmentioning

confidence: 99%

“…This discovery should be of high interest given, on one hand, the scarcity of multiferroic materials and, on the other hand, the technological promise of materials with JT distortions and electronic properties tunable by application of electric fields. [17][18][19][20][21] …”

Section: Introductionmentioning

confidence: 99%

“…More precisely, we discover that applying pressure to many magnetic rare-earth manganites RMnO 3 not only leads to the stabilization of the post-postperovskite structure but also induces pseudo Jahn-Teller effects that, in turn, yield a spontaneous electrical polarization via a previously unknown coupling. Interestingly, the latter coupling only involves the polarization and the mentioned JT distortion; this feature sets the new coupling apart from other trilinear effects, [17,18] in which a third structural distortion appears, as it strongly suggests the possibility of an easier control of JT effects and related electronic properties via the application of Multiferroic materials are currently attracting a lot of interest because of the cross-coupling between their electrical and magnetic properties, which has the potential to lead to novel devices. There is a relatively small number of multiferroics and, hence, various strategies have been proposed to design materials possessing both ordered electric and magnetic dipoles.…”

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Pressure‐Induced Multiferroics via Pseudo Jahn–Teller Effects and Novel Couplings

et al. 2016

Adv. Funct. Mater.

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of 7) 1604513PbHfS 3 , and SnHfS 3 . [2][3][4][5][6] Recent studies also revealed that iodate compounds, such as CH 3 NH 3 PbI 3 (which presents a high photovoltaic conversion) and CsSnI 3 can also crystallize in the NH 4 CdCl 3 -type structure. [7,8] Xu et al. further predicted, by using a first-principles-based genetic algorithm, that the NH 4 CdCl 3 -type structure can also become the ground state of many ABO 3 oxides and ABF 3 fluorites, when under high enough pressure. [9] Considering its generality and its occurrence after the perovskite (Pv) and post-perovskite (pPv) structures when gradually increasing the hydrostatic pressure in various ABO 3 and ABF 3 compounds, the NH 4 CdCl 3 -type structure is named as post-post-perovskite (ppPv) in ref.[9] -which is the convention we will also adopt in this paper.Interestingly, as far as we can tell, the post-post-perovskite structure has never been found (or predicted) to display an electrical polarization or the so-called Jahn-Teller (JT) distortions -intimately related to magnetism and electronic structure -in any material, including ABO 3 and ABF 3 systems. This is in line with the common belief that hydrostatic pressure suppresses structural distortions of the type that are typically related to electric polarization and Jahn-Teller effects. [10][11][12][13] For instance, experimental and computational works both reported that JT distortions of LaMnO 3 perovskite are reduced under pressure until potentially fully vanishing for a high enough compression. [11][12][13] Similarly, polarization typically results from a competition between long-range Coulomb interactions (which favor ferroelectricity) and short-range interactions (which favor the paraelectric structure), [14] and pressure tips this delicate balance in favor of short-range repulsive effects, thus favoring the paraelectric state. [15,16] Here we use first-principles simulations to predict that such beliefs have to be revisited. More precisely, we discover that applying pressure to many magnetic rare-earth manganites RMnO 3 not only leads to the stabilization of the post-postperovskite structure but also induces pseudo Jahn-Teller effects that, in turn, yield a spontaneous electrical polarization via a previously unknown coupling. Interestingly, the latter coupling only involves the polarization and the mentioned JT distortion; this feature sets the new coupling apart from other trilinear effects, [17,18] in which a third structural distortion appears, as it strongly suggests the possibility of an easier control of JT effects and related electronic properties via the application of Multiferroic materials are currently attracting a lot of interest because of the cross-coupling between their electrical and magnetic properties, which has the potential to lead to novel devices. There is a relatively small number of multiferroics and, hence, various strategies have been proposed to design materials possessing both ordered electric and magnetic dipoles. However, one strategy that has been scarcely investigated...

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Electric Field Control of Jahn-Teller Distortions in Bulk Perovskites

Cited by 46 publications

References 60 publications

Charge-Order-Induced Ferroelectricity inLaVO3/SrVO3Superlattices

Charge-Order-Induced Ferroelectricity inLaVO3/SrVO3Superlattices

Dynamics of antipolar distortions

Pressure‐Induced Multiferroics via Pseudo Jahn–Teller Effects and Novel Couplings

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