Capturing 3D atomic defects and phonon localization at the 2D heterostructure interface

The three-dimensional (3D) local atomic structures and crystal defects at the interfaces of heterostructures control their electronic, magnetic, optical, catalytic, and topological quantum properties but have thus far eluded any direct experimental determination. Here, we use atomic electron tomogra...

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Bibliographic Details
Published in:Science advances 2021-09, Vol.7 (38), p.eabi6699-eabi6699
Main Authors: Tian, Xuezeng, Yan, Xingxu, Varnavides, Georgios, Yuan, Yakun, Kim, Dennis S, Ciccarino, Christopher J, Anikeeva, Polina, Li, Ming-Yang, Li, Lain-Jong, Narang, Prineha, Pan, Xiaoqing, Miao, Jianwei
Format: Article
Language:English
Subjects:
Condensed Matter Physics
ENGINEERING
Physical and Materials Sciences
SciAdv r-articles
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Summary:The three-dimensional (3D) local atomic structures and crystal defects at the interfaces of heterostructures control their electronic, magnetic, optical, catalytic, and topological quantum properties but have thus far eluded any direct experimental determination. Here, we use atomic electron tomography to determine the 3D local atomic positions at the interface of a MoS -WSe heterojunction with picometer precision and correlate 3D atomic defects with localized vibrational properties at the epitaxial interface. We observe point defects, bond distortion, and atomic-scale ripples and measure the full 3D strain tensor at the heterointerface. By using the experimental 3D atomic coordinates as direct input to first-principles calculations, we reveal new phonon modes localized at the interface, which are corroborated by spatially resolved electron energy-loss spectroscopy. We expect that this work will pave the way for correlating structure-property relationships of a wide range of heterostructure interfaces at the single-atom level.
ISSN:2375-2548
2375-2548
DOI:10.1126/sciadv.abi6699