AI Article Synopsis
- Moiré superlattices exhibit magnification effects influenced by mechanical changes and atomic rearrangements, leading to diverse structural morphologies like hexagons and deformed shapes.
- Using techniques like scanning tunneling microscopy, researchers found that a combination of extrinsic strain and intrinsic atom changes drives this structural evolution, resulting in localized strain within the moiré patterns.
- Interestingly, instead of the expected electronic changes at the valence band edge, the study reveals significant conduction band modulation due to local intralayer strain, which can reach up to 300 meV in certain moiré configurations.
Article Abstract
As a lattice interference effect, moiré superlattices feature a magnification effect that they respond sensitively to both the extrinsic mechanical perturbations and intrinsic atomic reconstructions. Here, using scanning tunneling microscopy and spectroscopy, we observe that long-wavelength WS superlattices are reconstructed into various moiré morphologies, ranging from regular hexagons to heavily deformed ones. We show that a dedicated interplay between the extrinsic nonuniform heterostrain and the intrinsic atomic reconstruction is responsible for this interesting moiré structure evolution. Importantly, the interplay between these two factors also introduces a local inhomogeneous intralayer strain within a moiré. Contrary to the commonly reported electronic modulation that occurred at the valence band edge due to interlayer hybridization, we find that this local intralayer strain induces a strong modulation at point of the conduction band, reaching up to 300 meV in the heavily deformed moiré. Our microscopic explorations provide valuable information in understanding the intriguing physics in TMD moirés.
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| http://dx.doi.org/10.1021/acs.nanolett.2c02418 | DOI Listing |
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