Two-dimensional ferroelasticity in van der Waals β’-In2Se3

Xu, Chao; Mao, Jianfeng; Guo, Xuyun; Yan, Shanru; Chen, Yan‐Cong; Lo, Tsz Wing; Chen, Changsheng; Lei, Dangyuan; Luo, Xin; Hao, Jian; Zheng, Changxi; Zhu, Ye

doi:10.1038/s41467-021-23882-7

Cited by 63 publications

(67 citation statements)

References 59 publications

(69 reference statements)

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“…Benefiting from the antiparallel arrangement of electric dipoles within sublattices, null polarization is obtained on the unit cell scale. Typical AFE systems include PbZrO 3 , AgNbO 3 , NaNbO 3 , HfO 2 [64][65][66][67][68][69][70][71][72] and recently reported 2D van der Waals AFE β'-In 2 Se 3 [73,74]. From the perspective of lattice dynamics, the emergence of antiferroelectricity is a consequence of competing lattice instabilities [10,11], which are manifested by delicate structural orders [66,75].…”

Section: Structural Features and Phase Transitions In Antiferroelectricsmentioning

confidence: 99%

Structural Phase Transition and In-Situ Energy Storage Pathway in Nonpolar Materials: A Review

2021

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Benefitting from exceptional energy storage performance, dielectric-based capacitors are playing increasingly important roles in advanced electronics and high-power electrical systems. Nevertheless, a series of unresolved structural puzzles represent obstacles to further improving the energy storage performance. Compared with ferroelectrics and linear dielectrics, antiferroelectric materials have unique advantages in unlocking these puzzles due to the inherent coupling of structural transitions with the energy storage process. In this review, we summarize the most recent studies about in-situ structural phase transitions in PbZrO3-based and NaNbO3-based systems. In the context of the ultrahigh energy storage density of SrTiO3-based capacitors, we highlight the necessity of extending the concept of antiferroelectric-to-ferroelectric (AFE-to-FE) transition to broader antiferrodistortive-to-ferrodistortive (AFD-to-FD) transition for materials that are simultaneously ferroelastic. Combining discussion of the factors driving ferroelectricity, electric-field-driven metal-to-insulator transition in a (La1−xSrx)MnO3 electrode is emphasized to determine the role of ionic migration in improving the storage performance. We believe that this review, aiming at depicting a clearer structure–property relationship, will be of benefit for researchers who wish to carry out cutting-edge structure and energy storage exploration.

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Section: Structural Features and Phase Transitions In Antiferroelectricsmentioning

confidence: 99%

Structural Phase Transition and In-Situ Energy Storage Pathway in Nonpolar Materials: A Review

2021

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“…Angle-resolved polarized optical microscopy images are shown in Figs. 3b–d and S9 ; the intensity contrast is caused by the changing orientation of the optical axes of the ferroelastic domain relative to the polarized light direction, thus allowing the spontaneous strain direction in each ferroelastic domain to be determined 45 , 46 . Based on this, we can deduce that the strain axis has C 3V symmetry, with three equivalent strain axes that are 120° apart.…”

Section: Resultsmentioning

confidence: 99%

“…Meanwhile, newly nucleated domains B are created. The expansion of B domain can be explained by the fact that its spontaneous strain direction may be aligned at a smaller angle to the direction of the applied stress 46 . After removing the external bending stress, a reversible switching from bright A domain to dark B domain occurs (Fig.…”

Section: Resultsmentioning

confidence: 99%

Intercalation-driven ferroelectric-to-ferroelastic conversion in a layered hybrid perovskite crystal

Wong

et al. 2022

Nat Commun

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Two-dimensional (2D) organic-inorganic hybrid perovskites have attracted intense interests due to their quantum well structure and tunable excitonic properties. As an alternative to the well-studied divalent metal hybrid perovskite based on Pb2+, Sn2+ and Cu2+, the trivalent metal-based (eg. Sb3+ with ns2 outer-shell electronic configuration) hybrid perovskite with the A3M2X9 formula (A = monovalent cations, M = trivalent metal, X = halide) offer intriguing possibilities for engineering ferroic properties. Here, we synthesized 2D ferroelectric hybrid perovskite (TMA)3Sb2Cl9 with measurable in-plane and out-of-plane polarization. Interestingly, (TMA)3Sb2Cl9 can be intercalated with FeCl4 ions to form a ferroelastic and piezoelectric single crystal, (TMA)4-Fe(iii)Cl4-Sb2Cl9. Density functional theory calculations were carried out to investigate the unusual mechanism of ferroelectric-ferroelastic crossover in these crystals.

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“…The onset strain of domain reconstruction is ≈1%, which is much lower than that of other materials. [ 26 ] Second, the Raman shift shows hysteresis according to external strain owing to the energetically degenerated orientation states. Third, the plateau of the Raman shift is observed after the onset of domain reconstruction.…”

Section: Ferroelasticity In Res2mentioning

confidence: 99%

Ferroelastic–Ferroelectric Multiferroicity in van der Waals Rhenium Dichalcogenides

et al. 2022

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2D multiferroics with combined ferroic orders have gained attention owing to their novel functionality and underlying science. Intrinsic ferroelastic–ferroelectric multiferroicity in single‐crystalline van der Waals rhenium dichalcogenides, whose symmetries are broken by the Peierls distortion and layer‐stacking order, is demonstrated. Ferroelastic switching of the domain orientation and accompanying anisotropic properties is achieved with 1% uniaxial strain using the polymer encapsulation method. Based on the electron localization function and bond dissociation energy of the Re–Re bonds, the change in bond configuration during the evolution of the domain wall and the preferred switching between the two specific orientation states are explained. Furthermore, the ferroelastic switching of ferroelectric polarization is confirmed using the photovoltaic effect. The study provides insights into the reversible bond‐switching process and potential applications based on 2D multiferroicity.

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Two-dimensional ferroelasticity in van der Waals β’-In2Se3

Cited by 63 publications

References 59 publications

Structural Phase Transition and In-Situ Energy Storage Pathway in Nonpolar Materials: A Review

Structural Phase Transition and In-Situ Energy Storage Pathway in Nonpolar Materials: A Review

Intercalation-driven ferroelectric-to-ferroelastic conversion in a layered hybrid perovskite crystal

Ferroelastic–Ferroelectric Multiferroicity in van der Waals Rhenium Dichalcogenides

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