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Hauptverfasser: Park, Daesung, Park, Changwon, Yananose, Kunihiro, Ko, Eunjung, Kim, Byunghyun, Engelke, Rebecca, Zhang, Xi, Davydov, Konstantin, Green, Matthew, Kim, Hyun-Mi, Park, Sang Hwa, Lee, Jae Heon, Kim, Seul-Gi, Kim, Hyeongkeun, Watanabe, Kenji, Taniguchi, Takashi, Yang, Sang Mo, Wang, Ke, Kim, Philip, Son, Young-Woo, Yoo, Hyobin
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2402.15760
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author Park, Daesung
Park, Changwon
Yananose, Kunihiro
Ko, Eunjung
Kim, Byunghyun
Engelke, Rebecca
Zhang, Xi
Davydov, Konstantin
Green, Matthew
Kim, Hyun-Mi
Park, Sang Hwa
Lee, Jae Heon
Kim, Seul-Gi
Kim, Hyeongkeun
Watanabe, Kenji
Taniguchi, Takashi
Yang, Sang Mo
Wang, Ke
Kim, Philip
Son, Young-Woo
Yoo, Hyobin
author_facet Park, Daesung
Park, Changwon
Yananose, Kunihiro
Ko, Eunjung
Kim, Byunghyun
Engelke, Rebecca
Zhang, Xi
Davydov, Konstantin
Green, Matthew
Kim, Hyun-Mi
Park, Sang Hwa
Lee, Jae Heon
Kim, Seul-Gi
Kim, Hyeongkeun
Watanabe, Kenji
Taniguchi, Takashi
Yang, Sang Mo
Wang, Ke
Kim, Philip
Son, Young-Woo
Yoo, Hyobin
contents Imposing incommensurable periodicity on the periodic atomic lattice can lead to complex structural phases consisting of locally periodic structure bounded by topological defects. Twisted trilayer graphene (TTG) is an ideal material platform to study the interplay between different atomic periodicities, which can be tuned by twist angles between the layers, leading to moiré-of-moiré lattices. Interlayer and intralayer interactions between two interfaces in TTG transform this moiré-of-moiré lattice into an intricate network of domain structures at small twist angles, which can harbor exotic electronic behaviors. Here we report a complete structural phase diagram of TTG with atomic scale lattice reconstruction. Using transmission electron microscopy combined with a new interatomic potential simulation, we show several large-scale moiré lattices, including triangular, kagome, and a corner-shared hexagram-shaped domain pattern. Each domain is bounded by a two-dimensional network of domain wall lattices. In the limit of small twist angles, two competing structural orders-rhombohedral and Bernal stackings-with a slight energy difference, cause unconventional lattice reconstruction with spontaneous symmetry breaking and nematic instability, highlighting the importance of long-range interlayer interactions across entire van der Waals layers. The diverse tessellation of distinct domains, whose topological network can be tuned by the adjustment of the twist angles, establishes TTG as a platform for exploring the interplay between emerging quantum properties and controllable nontrivial lattices.
format Preprint
id arxiv_https___arxiv_org_abs_2402_15760
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Unconventional domain tessellations in moiré-of-moiré lattices
Park, Daesung
Park, Changwon
Yananose, Kunihiro
Ko, Eunjung
Kim, Byunghyun
Engelke, Rebecca
Zhang, Xi
Davydov, Konstantin
Green, Matthew
Kim, Hyun-Mi
Park, Sang Hwa
Lee, Jae Heon
Kim, Seul-Gi
Kim, Hyeongkeun
Watanabe, Kenji
Taniguchi, Takashi
Yang, Sang Mo
Wang, Ke
Kim, Philip
Son, Young-Woo
Yoo, Hyobin
Materials Science
Imposing incommensurable periodicity on the periodic atomic lattice can lead to complex structural phases consisting of locally periodic structure bounded by topological defects. Twisted trilayer graphene (TTG) is an ideal material platform to study the interplay between different atomic periodicities, which can be tuned by twist angles between the layers, leading to moiré-of-moiré lattices. Interlayer and intralayer interactions between two interfaces in TTG transform this moiré-of-moiré lattice into an intricate network of domain structures at small twist angles, which can harbor exotic electronic behaviors. Here we report a complete structural phase diagram of TTG with atomic scale lattice reconstruction. Using transmission electron microscopy combined with a new interatomic potential simulation, we show several large-scale moiré lattices, including triangular, kagome, and a corner-shared hexagram-shaped domain pattern. Each domain is bounded by a two-dimensional network of domain wall lattices. In the limit of small twist angles, two competing structural orders-rhombohedral and Bernal stackings-with a slight energy difference, cause unconventional lattice reconstruction with spontaneous symmetry breaking and nematic instability, highlighting the importance of long-range interlayer interactions across entire van der Waals layers. The diverse tessellation of distinct domains, whose topological network can be tuned by the adjustment of the twist angles, establishes TTG as a platform for exploring the interplay between emerging quantum properties and controllable nontrivial lattices.
title Unconventional domain tessellations in moiré-of-moiré lattices
topic Materials Science
url https://arxiv.org/abs/2402.15760