Salvato in:
Dettagli Bibliografici
Autori principali: Xiao, Hanbo, Gao, Han, Li, Min, Chen, Fanqiang, Li, Qiao, Li, Yiwei, Wang, Meixiao, Zhu, Fangyuan, Yang, Lexian, Miao, Feng, Chen, Yulin, Chen, Cheng, Cheng, Bin, Liu, Jianpeng, Liu, Zhongkai
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2405.11893
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866911885532594176
author Xiao, Hanbo
Gao, Han
Li, Min
Chen, Fanqiang
Li, Qiao
Li, Yiwei
Wang, Meixiao
Zhu, Fangyuan
Yang, Lexian
Miao, Feng
Chen, Yulin
Chen, Cheng
Cheng, Bin
Liu, Jianpeng
Liu, Zhongkai
author_facet Xiao, Hanbo
Gao, Han
Li, Min
Chen, Fanqiang
Li, Qiao
Li, Yiwei
Wang, Meixiao
Zhu, Fangyuan
Yang, Lexian
Miao, Feng
Chen, Yulin
Chen, Cheng
Cheng, Bin
Liu, Jianpeng
Liu, Zhongkai
contents Over the years, great efforts have been devoted in introducing a sizable and tunable band gap in graphene for its potential application in next-generation electronic devices. The primary challenge in modulating this gap has been the absence of a direct method for observing changes of the band gap in momentum space. In this study, we employ advanced spatial- and angle-resolved photoemission spectroscopy technique to directly visualize the gap formation in bilayer graphene, modulated by both displacement fields and moiré potentials. The application of displacement field via in-situ electrostatic gating introduces a sizable and tunable electronic bandgap, proportional to the field strength up to 100 meV. Meanwhile, the moiré potential, induced by aligning the underlying hexagonal boron nitride substrate, extends the bandgap by ~ 20 meV. Theoretical calculations, effectively capture the experimental observations. Our investigation provides a quantitative understanding of how these two mechanisms collaboratively modulate the band gap in bilayer graphene, offering valuable guidance for the design of graphene-based electronic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2405_11893
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Tunable moiré bandgap in hBN-aligned bilayer graphene device with in-situ electrostatic gating
Xiao, Hanbo
Gao, Han
Li, Min
Chen, Fanqiang
Li, Qiao
Li, Yiwei
Wang, Meixiao
Zhu, Fangyuan
Yang, Lexian
Miao, Feng
Chen, Yulin
Chen, Cheng
Cheng, Bin
Liu, Jianpeng
Liu, Zhongkai
Mesoscale and Nanoscale Physics
Materials Science
Over the years, great efforts have been devoted in introducing a sizable and tunable band gap in graphene for its potential application in next-generation electronic devices. The primary challenge in modulating this gap has been the absence of a direct method for observing changes of the band gap in momentum space. In this study, we employ advanced spatial- and angle-resolved photoemission spectroscopy technique to directly visualize the gap formation in bilayer graphene, modulated by both displacement fields and moiré potentials. The application of displacement field via in-situ electrostatic gating introduces a sizable and tunable electronic bandgap, proportional to the field strength up to 100 meV. Meanwhile, the moiré potential, induced by aligning the underlying hexagonal boron nitride substrate, extends the bandgap by ~ 20 meV. Theoretical calculations, effectively capture the experimental observations. Our investigation provides a quantitative understanding of how these two mechanisms collaboratively modulate the band gap in bilayer graphene, offering valuable guidance for the design of graphene-based electronic devices.
title Tunable moiré bandgap in hBN-aligned bilayer graphene device with in-situ electrostatic gating
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2405.11893