Flat AgTe Honeycomb Monolayer on Ag(111)

The intriguing properties of graphene have inspired the pursuit of two-dimensional materials with honeycomb structure. Here we achieved the synthesis of a monolayer transition-metal monochalcogenide AgTe on Ag(111) by tellurization of the substrate. High-resolution scanning tunneling microscopy, com...

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Published in:The journal of physical chemistry letters 2019-04, Vol.10 (8), p.1866-1871
Main Authors: Liu, Bing, Liu, Jian, Miao, Guangyao, Xue, Siwei, Zhang, Shuyuan, Liu, Lixia, Huang, Xiaochun, Zhu, Xuetao, Meng, Sheng, Guo, Jiandong, Liu, Miao, Wang, Weihua
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container_issue 8
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container_title The journal of physical chemistry letters
container_volume 10
creator Liu, Bing
Liu, Jian
Miao, Guangyao
Xue, Siwei
Zhang, Shuyuan
Liu, Lixia
Huang, Xiaochun
Zhu, Xuetao
Meng, Sheng
Guo, Jiandong
Liu, Miao
Wang, Weihua
description The intriguing properties of graphene have inspired the pursuit of two-dimensional materials with honeycomb structure. Here we achieved the synthesis of a monolayer transition-metal monochalcogenide AgTe on Ag(111) by tellurization of the substrate. High-resolution scanning tunneling microscopy, combined with low-energy electron diffraction, angle-resolved photoemission spectroscopy, and density functional theory calculations, demonstrates the planar honeycomb structure of AgTe. The first-principles calculations further predict that, protected by the in-plane mirror reflection symmetry, there are two Dirac node-line fermions existing in the free-standing AgTe when spin–orbit coupling (SOC) is ignored. In fact, the SOC leads to the gap opening, resulting in the emergence of the topologically nontrivial quantum spin Hall edge state. Importantly, our experiments evidence the chemical stability of the monolayer AgTe in ambient conditions, making it possible to study AgTe by more ex situ measurements and even to utilize AgTe in future electronic devices.
doi_str_mv 10.1021/acs.jpclett.9b00339
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title Flat AgTe Honeycomb Monolayer on Ag(111)
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