AI Article Synopsis
- van Hove singularities (VHS's) are crucial for understanding the electronic and thermodynamic properties of crystalline solids, particularly during critical points where Fermi surface connectivity and topological properties change.
- The research focuses on twisted bilayer graphene, where the ability to adjust the angle between graphene layers allows for precise exploration of VHS's effects through voltage manipulation.
- The study reveals a topological phase transition, marked by an abrupt shift from electron to hole behavior, a change in Berry phase, and unique patterns of integer quantum Hall states around the VHS.
Article Abstract
van Hove singularities (VHS's) in the density of states play an outstanding and diverse role for the electronic and thermodynamic properties of crystalline solids. At the critical point the Fermi surface connectivity changes, and topological properties undergo a transition. Opportunities to systematically pass a VHS at the turn of a voltage knob and study its diverse impact are however rare. With the advent of van der Waals heterostructures, control over the atomic registry of neighboring graphene layers offers an unprecedented tool to generate a low energy VHS easily accessible with conventional gating. Here we have addressed magnetotransport when the chemical potential crosses the twist angle induced VHS in twisted bilayer graphene. A topological phase transition is experimentally disclosed in the abrupt conversion of electrons to holes or vice versa, a loss of a nonzero Berry phase and distinct sequences of integer quantum Hall states above and below the singularity.
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| http://dx.doi.org/10.1021/acs.nanolett.6b01906 | DOI Listing |
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