Asymmetric correlated states in twisted monolayer-bilayer graphene
ORAL
Abstract
In twisted monolayer-bilayer graphene massless and massive Dirac fermions mix together and lead to topological bands, asymmetric correlated states and superconductivity-like non-linear current-voltage characteristics. In this theoretical work, we first develop an analytical model to explain the observed asymmetry in formation of correlated states with respect to carrier density and displacement field [1]. Using the linearized gap equation method, we calculate the stability and critical temperature for different symmetry breaking phases, including spin density waves, charge density waves, and valley ordered phases. We compare our theoretical findings with available experimental data.
This work was supported by the Singapore National Research Foundation Investigator Award (Grant No. NRF-NRFI06-2020-0003).
[1] Shuigang Xu, et al. " Tunable van Hove singularities and correlated states in twisted monolayer–bilayer graphene." Nature Physics 17, (2021)
This work was supported by the Singapore National Research Foundation Investigator Award (Grant No. NRF-NRFI06-2020-0003).
[1] Shuigang Xu, et al. " Tunable van Hove singularities and correlated states in twisted monolayer–bilayer graphene." Nature Physics 17, (2021)
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Presenters
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Mohammed M Al Ezzi
Natl Univ of Singapore
Authors
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Mohammed M Al Ezzi
Natl Univ of Singapore
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Xingyu Gu
National University of Singapore
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Alexandra Carvalho
National University of Singapore
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Vladimir Falko
Department of Physics and Astronomy, University of Manchester, The University of Manchester, Manchester University
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Kostya Novoselov
Institute for Functional Intelligent Materials, National University of Singapore, National University of Singapore
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Antonio Castro Neto
National University of Singapore
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Shaffique Adam
Natl Univ of Singapore, National University of Singapore