Sliding van der Waals polytypes

Maayan Vizner Stern; Simon Salleh Atri; Moshe Ben Shalom

doi:10.1038/s42254-024-00781-6

Sliding van der Waals polytypes

Maayan Vizner Stern, Simon Salleh Atri, Moshe Ben Shalom

School of Physics and Astronomy

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

Compared with electronic phase transitions, structural phase transitions of crystals are challenging to control owing to the energy cost of breaking dense solid bonds. Recently, electric field switching of stacking configuration between honeycomb layers, held together by relatively weak van der Waals attractions, has been demonstrated. Different structural configurations — or polytypes — of 2D van der Waals materials host diverse electronic orders such as intrinsic polarizations and magnetism. In this Perspective, we discuss stacking energies, symmetries and orbital overlaps that underlie the band structures and internal charge distributions of these polytypes and their effect on properties such as interfacial ferroelectricity, ladder-like cumulative polarization, superconductivity and orbital magnetic orders. We also identify the challenges of harnessing these switching mechanisms for rapid, local and practical multiferroic devices.

Original language	Danish
Article number	e2115703118
Pages (from-to)	50-61
Number of pages	12
Journal	Nature Reviews Physics
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s42254-024-00781-6
State	Published - Jan 2025

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1038/s42254-024-00781-6

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title = "Sliding van der Waals polytypes",

abstract = "Compared with electronic phase transitions, structural phase transitions of crystals are challenging to control owing to the energy cost of breaking dense solid bonds. Recently, electric field switching of stacking configuration between honeycomb layers, held together by relatively weak van der Waals attractions, has been demonstrated. Different structural configurations — or polytypes — of 2D van der Waals materials host diverse electronic orders such as intrinsic polarizations and magnetism. In this Perspective, we discuss stacking energies, symmetries and orbital overlaps that underlie the band structures and internal charge distributions of these polytypes and their effect on properties such as interfacial ferroelectricity, ladder-like cumulative polarization, superconductivity and orbital magnetic orders. We also identify the challenges of harnessing these switching mechanisms for rapid, local and practical multiferroic devices.",

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N2 - Compared with electronic phase transitions, structural phase transitions of crystals are challenging to control owing to the energy cost of breaking dense solid bonds. Recently, electric field switching of stacking configuration between honeycomb layers, held together by relatively weak van der Waals attractions, has been demonstrated. Different structural configurations — or polytypes — of 2D van der Waals materials host diverse electronic orders such as intrinsic polarizations and magnetism. In this Perspective, we discuss stacking energies, symmetries and orbital overlaps that underlie the band structures and internal charge distributions of these polytypes and their effect on properties such as interfacial ferroelectricity, ladder-like cumulative polarization, superconductivity and orbital magnetic orders. We also identify the challenges of harnessing these switching mechanisms for rapid, local and practical multiferroic devices.

AB - Compared with electronic phase transitions, structural phase transitions of crystals are challenging to control owing to the energy cost of breaking dense solid bonds. Recently, electric field switching of stacking configuration between honeycomb layers, held together by relatively weak van der Waals attractions, has been demonstrated. Different structural configurations — or polytypes — of 2D van der Waals materials host diverse electronic orders such as intrinsic polarizations and magnetism. In this Perspective, we discuss stacking energies, symmetries and orbital overlaps that underlie the band structures and internal charge distributions of these polytypes and their effect on properties such as interfacial ferroelectricity, ladder-like cumulative polarization, superconductivity and orbital magnetic orders. We also identify the challenges of harnessing these switching mechanisms for rapid, local and practical multiferroic devices.

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Sliding van der Waals polytypes

Abstract

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