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Polar and phase domain walls with conducting interfacial states in a Weyl semimetal MoTe2.


ABSTRACT: Much of the dramatic growth in research on topological materials has focused on topologically protected surface states. While the domain walls of topological materials such as Weyl semimetals with broken inversion or time-reversal symmetry can provide a hunting ground for exploring topological interfacial states, such investigations have received little attention to date. Here, utilizing in-situ cryogenic transmission electron microscopy combined with first-principles calculations, we discover intriguing domain-wall structures in MoTe2, both between polar variants of the low-temperature(T) Weyl phase, and between this and the high-T higher-order topological phase. We demonstrate how polar domain walls can be manipulated with electron beams and show that phase domain walls tend to form superlattice-like structures along the c axis. Scanning tunneling microscopy indicates a possible signature of a conducting hinge state at phase domain walls. Our results open avenues for investigating topological interfacial states and unveiling multifunctional aspects of domain walls in topological materials.

SUBMITTER: Huang FT 

PROVIDER: S-EPMC6746811 | biostudies-other | 2019 Sep

REPOSITORIES: biostudies-other

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Polar and phase domain walls with conducting interfacial states in a Weyl semimetal MoTe<sub>2</sub>.

Huang Fei-Ting FT   Joon Lim Seong S   Singh Sobhit S   Kim Jinwoong J   Zhang Lunyong L   Kim Jae-Wook JW   Chu Ming-Wen MW   Rabe Karin M KM   Vanderbilt David D   Cheong Sang-Wook SW  

Nature communications 20190916 1


Much of the dramatic growth in research on topological materials has focused on topologically protected surface states. While the domain walls of topological materials such as Weyl semimetals with broken inversion or time-reversal symmetry can provide a hunting ground for exploring topological interfacial states, such investigations have received little attention to date. Here, utilizing in-situ cryogenic transmission electron microscopy combined with first-principles calculations, we discover i  ...[more]

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