Switchable Rashba anisotropy in layered hybrid organic–inorganic perovskite by hybrid improper ferroelectricity

Wang, Fei; Gao, Heng; Graaf, Coen de; Poblet, Josep M.; Campbell, Branton J.; Stroppa, Alessandro

doi:10.1038/s41524-020-00450-z

Cited by 29 publications

(26 citation statements)

References 58 publications

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“…The structures observed in these compounds are obviously dictated by the total energetics of the system, which will depend on a subtle interplay and co-operation between the molecular moieties and the inorganic framework. An interesting recent example (Park et al, 2019) which leads to unusual physical properties (Wang et al, 2020) is that of [C 6 H 16 N 2 ]PbI 4 (1939809 and 1831525, Table 4), which exhibits an order-disorder transition of the 4-aminopiperidine, but this hardly changes the distortions within the [PbI 4 ] 1 layer itself. In this section, we will consider structural trends across this family of compounds, and we highlight a few interesting cases of interlayer cation influence on the overall structure.…”

Section: More Complex Derivativesmentioning

confidence: 99%

Structural chemistry of layered lead halide perovskites containing single octahedral layers

McNulty

Lightfoot

2021

Int Union Crystallogr J

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We present a comprehensive review of the structural chemistry of hybrid lead halides of stoichiometry APbX 4, A 2PbX4 or A A′PbX 4, where A and A′ are organic ammonium cations and X = Cl, Br or I. These compounds may be considered as layered perovskites, containing isolated, infinite layers of corner-sharing PbX 4 octahedra separated by the organic species. First, over 250 crystal structures were extracted from the CCDC and classified in terms of unit-cell metrics and crystal symmetry. Symmetry mode analysis was then used to identify the nature of key structural distortions of the [PbX 4]∞ layers. Two generic types of distortion are prevalent in this family: tilting of the octahedral units and shifts of the inorganic layers relative to each other. Although the octahedral tilting modes are well known in the crystallography of purely inorganic perovskites, the additional layer-shift modes are shown to enormously enrich the structural options available in layered hybrid perovskites. Some examples and trends are discussed in more detail in order to show how the nature of the interlayer organic species can influence the overall structural architecture; although the main aim of the paper is to encourage workers in the field to make use of the systematic crystallographic methods used here to further understand and rationalize their own compounds, and perhaps to be able to design-in particular structural features in future work.

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Section: More Complex Derivativesmentioning

confidence: 99%

Structural chemistry of layered lead halide perovskites containing single octahedral layers

McNulty

Lightfoot

2021

Int Union Crystallogr J

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“…The spin degree of freedom (spin-up and spin-down) of an electron is an intrinsic property and relatively easier to manipulate in the presence of a magnetic field as compared to the motion of the electronic charge. Recent experiments have demonstrated the usage of the spin degree of freedom to store and manipulate data that can be the fastest and effective way to store a large amount of data for a long time and can pave the way for next-generation high-speed quantum information devices. − The 21st century witnessed significant technological advancements in electronics, data storage devices, quantum computing (spintronics/valleytronics), etc. − Spintronics utilizes the spin of electrons to gather and store information that leads to the next-generation data storage devices, magnetic sensor applications, etc. The spintronic device consists mainly of two ferromagnetic electrodes in which one acts as an electron emitter with a particular spin direction and the other acts as a collector or spin-filter of the emitted electron and a semiconducting channel. , However, the development of a very efficient, low-power spintronic device is confronted with many challenges such as high magnetic anisotropy, long spin lifetime, modulation of spin current, and temperature-dependent spin properties .…”

Section: Introductionmentioning

confidence: 99%

Spin-Current Modulation in Hexagonal Buckled ZnTe and CdTe Monolayers for Self-Powered Flexible-Piezo-Spintronic Devices

Mohanta¹,

IS²,

Kishore³

et al. 2021

ACS Appl. Mater. Interfaces

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The next-generation spintronic device demands the gated control of spin transport across the semiconducting channel through the replacement of the external gate voltage source by the piezo potential, as experimentally demonstrated in Zhu et al. ACS Nano, 2018, 12 (2), 1811−1820. Consequently, a high level of out-of-plane piezoelectricity together with a large Rashba spin splitting is sought after in semiconducting channel materials. Inspired by this experiment, a new hexagonal buckled two-dimensional (2D) semiconductor, ZnTe, and its iso-electronic partner, CdTe, are proposed herewith. These 2D materials show a strong spin-orbit coupling (SOC), which is evidenced by a large Rashba constant of 1.06 and 1.27 eV•Å, respectively, in ZnTe and CdTe monolayers. Moreover, these Rashba semiconductors exhibit a giant out-of-plane piezoelectric coefficient (d 33 ) = 88.68 and 172.61 pm/V, and can thereby generate a high piezo potential for gating purposes in spin field-effect transistors (spin-FETs). While the low elastic stiffness implies the mechanical flexibility or stretchability in these monolayers. The Rashba constants are found to be effectively modulated via external perturbations, such as strain and electric field. The wide band gap provides ample room for modulation in its electronic properties via external perturbations. Such scope is severely limited in previously reported narrow band gap Rashba semiconductors. The fascinating results found in this work indicate their great potential for applications in next-generation self-powered flexible-piezo-spintronic devices. Moreover, a new class of hexagonal buckled ZnX (X: S, Se, or Te) monolayers is proposed herein based on their previously synthesized bulk counterparts, while their electronic, mechanical, piezoelectric, and thermal properties have been thoroughly investigated using the state-of-art density functional theory (DFT).

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“…Additionally, a complex interplay of electrostatic requirements, steric effects, intermolecular interactions, and hydrogen-bonding associated with the organic cations engenders intricate distortions within the inorganic layers that have been previously correlated with exciton energy shifts 17,18 and exciton self-trapping 19 . When such distortions break the inversion symmetry of the inorganic layer, Rashba/Dresselhaus spin-splitting can emerge due to spin-orbit coupling (SOC) [20][21][22][23][24] . Rashba/Dresselhaus spinsplitting is a relativistic quantum phenomenon in condensed matter that leads to important physical manifestations for emerging spin-orbitronic devices, including intrinsic spin-Hall effect 25 , gate-controlled spin precession 26 , (inverse) spin galvanic effects, photogalvanic effects 27 , and chiroptic effects 28 , that rely on SOC-mediated manipulation of the spin degrees of freedom by electrical, optical, or magnetic means 22,25 .…”

mentioning

confidence: 99%

Structural descriptor for enhanced spin-splitting in 2D hybrid perovskites

et al. 2021

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Two-dimensional (2D) hybrid metal halide perovskites have emerged as outstanding optoelectronic materials and are potential hosts of Rashba/Dresselhaus spin-splitting for spin-selective transport and spin-orbitronics. However, a quantitative microscopic understanding of what controls the spin-splitting magnitude is generally lacking. Through crystallographic and first-principles studies on a broad array of chiral and achiral 2D perovskites, we demonstrate that a specific bond angle disparity connected with asymmetric tilting distortions of the metal halide octahedra breaks local inversion symmetry and strongly correlates with computed spin-splitting. This distortion metric can serve as a crystallographic descriptor for rapid discovery of potential candidate materials with strong spin-splitting. Our work establishes that, rather than the global space group, local inorganic layer distortions induced via appropriate organic cations provide a key design objective to achieve strong spin-splitting in perovskites. New chiral perovskites reported here couple a sizeable spin-splitting with chiral degrees of freedom and offer a unique paradigm of potential interest for spintronics.

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Switchable Rashba anisotropy in layered hybrid organic–inorganic perovskite by hybrid improper ferroelectricity

Cited by 29 publications

References 58 publications

Structural chemistry of layered lead halide perovskites containing single octahedral layers

Structural chemistry of layered lead halide perovskites containing single octahedral layers

Spin-Current Modulation in Hexagonal Buckled ZnTe and CdTe Monolayers for Self-Powered Flexible-Piezo-Spintronic Devices

Structural descriptor for enhanced spin-splitting in 2D hybrid perovskites

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