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Atomically thin 2D materials incorporated into van der Waals heterostructures are a promising platform to deterministically engineer quantum materials with atomically resolved thickness and abrupt interfaces across macroscopic length scales while retaining excellent material properties. Because 2D materials exhibit a wide range of electronic characteristics with properties that often rival conventional electronic materials — e.g., metals, semiconductors, insulators, and superconductors — it is possible to combine them in virtually infinite variety to achieve diverse heterostructures. Furthermore, the van der Waals interface enables interlayer twist engineering to modify the interlayer symmetry, periodic potential (moiré superlattice), and hybridization, which has resulted in novel quantum states of matter. Many of these heterostructures, especially those involving specific interlayer twist angles, would be otherwise infeasible through direct growth.
The Mannix Group is developing a unique set of in-house capabilities to systematically elucidate the fundamental structure-property relationships underpinning the growth of 2D materials and their inclusion into van der Waals heterostructures. Greater understanding will allow us to provide a platform for engineering the properties of matter at the atomic scale and offer guidance for emerging applications in novel electronics and in quantum information science.
To accomplish this, we employ: precise growth techniques such as chemical vapor deposition and molecular beam epitaxy; automated van der Waals assembly; and atomically-resolved microscopy including cryo-STM/AFM.
Atomically thin 2D materials incorporated into van der Waals heterostructures are a promising platform to deterministically engineer quantum materials with atomically resolved thickness and abrupt interfaces across macroscopic length scales while retaining excellent material properties. Because 2D materials exhibit a wide range of electronic characteristics with properties that often rival conventional electronic materials — e.g., metals, semiconductors, insulators, and superconductors — it is possible to combine them in virtually infinite variety to achieve diverse heterostructures. Furthermore, the van der Waals interface enables interlayer twist engineering to modify the interlayer symmetry, periodic potential (moiré superlattice), and hybridization, which has resulted in novel quantum states of matter. Many of these heterostructures, especially those involving specific interlayer twist angles, would be otherwise infeasible through direct growth.
The Mannix Group is developing a unique set of in-house capabilities to systematically elucidate the fundamental structure-property relationships underpinning the growth of 2D materials and their inclusion into van der Waals heterostructures. Greater understanding will allow us to provide a platform for engineering the properties of matter at the atomic scale and offer guidance for emerging applications in novel electronics and in quantum information science.
To accomplish this, we employ: precise growth techniques such as chemical vapor deposition and molecular beam epitaxy; automated van der Waals assembly; and atomically-resolved microscopy including cryo-STM/AFM.
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论文共 39 篇作者统计合作学者相似作者
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Marisa Hocking, Christina E. Henzinger, Steven Tran, Mihir Pendharkar, Nathan J. Bittner,Kenji Watanabe,Takashi Taniguchi, David Goldhaber-Gordon,Andrew J. Mannix
arxiv(2024)
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arxiv(2024)
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Mihir Pendharkar, Steven J Tran, Gregory Zaborski,Joe Finney,Aaron L Sharpe, Rupini V Kamat,Sandesh S Kalantre, Marisa Hocking, Nathan J Bittner,Kenji Watanabe,Takashi Taniguchi,Bede Pittenger,
Proceedings of the National Academy of Sciences of the United States of Americano. 10 (2024): e2314083121-e2314083121
Zhepeng Zhang,Lauren Hoang, Marisa Hocking,Jenny Hu, Gregory Zaborski Jr., Pooja Reddy, Johnny Dollard, David Goldhaber-Gordon,Tony F. Heinz,Eric Pop,Andrew J. Mannix
arxiv(2024)
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npj 2D Materials and Applicationsno. 1 (2023): 1-9
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Jerry Austin Yang,Robert Kevin Arran Bennett, Lauren Hoang,Zhepeng Zhang, Kamila Jewell Thompson,Andrew Jacob Mannix,E. Pop
arxiv(2023)
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Microscopy and Microanalysisno. S1 (2022): 1742-1744
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