Abstract
In two-dimensional heterostructures, crystalline atomic layers with differing lattice parameters can stack directly one on another. The resultant close proximity of atomic lattices with differing periodicity can lead to new phenomena. For umklapp processes, this opens the possibility for interlayer umklapp scattering, where interactions are mediated by the transfer of momenta to or from the lattice in the neighbouring layer. Using angle-resolved photoemission spectroscopy to study a graphene on InSe heterostructure, we present evidence that interlayer umklapp processes can cause hybridization between bands from neighbouring layers in regions of the Brillouin zone where bands from only one layer are expected, despite no evidence for Moiré-induced replica bands. This phenomenon manifests itself as ‘ghost’ anti-crossings in the InSe electronic dispersion. Applied to a range of suitable two-dimensional material pairs, this phenomenon of interlayer umklapp hybridization can be used to create strong mixing of their electronic states, giving a new tool for twist-controlled band structure engineering.
Highlights
Crystalline periodicity modifies the interpretation of the momentum conservation law for electronic and optical processes in solids
We demonstrate that interlayer umklapp processes in resonant tunnelling lead to the appearance of additional features in the hybridized band structures of 2DM heterostructures (2DHSs)
An example of such an effect is illustrated in figure 1, where angle-resolved photoemission spectroscopy with submicrometre spatial resolution has been used to probe the valence band structure in a graphene on InSe 2DHS
Summary
Attribution 4.0 licence. Keywords: ARPES, 2D materials, 2D heterostructures, umklapp scattering, twistronics Supplementary material for this article is available online maintain attribution to the author(s) and the title of the work, journal citation and DOI.
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