范德瓦尔斯力
白云母
制作
异质结
纳米技术
材料科学
定制
单层
云母
粘附
量子
超晶格
化学物理
光电子学
耗散系统
双层
石墨
夹持器
导电体
计算机科学
等离子体子
自组装
量子隧道
半导体
凝聚态物理
宏观量子现象
作者
Ian Babich,Timofey M. Savilov,Natalia A. Mamchik,Kristina Vaklinova,Nansi Zhou,Denis S. Baranov,Dmitrii A. Litvinov,Virgil Gavriliuc,Yue Yuan,Amoz Chua,Kenji Watanabe,Takashi Taniguchi,Mario Lanza,Maciej Koperski,Kostya S. Novoselov,Alexey I. Berdyugin,Makars Šiškins
标识
DOI:10.1038/s41467-026-72554-x
摘要
The advent of van der Waals (vdW) heterostructures has enabled formation of bespoke materials with atomic precision, where numerous quantum and topological phenomena have already been discovered. This atomic-layer tunability, however, comes at a cost: individual 2D layers must be picked up, moved, and placed in a deterministic manner while keeping their interfaces atomically clean. Recent advances in machine learning and robotics place even stronger emphasis on the deterministic aspect of vdW assembly. Current polymer-based transfer methods satisfy neither the determinism nor cleanliness requirements. To this end, solutions are needed where adhesion can be dynamically and deterministically controlled without leaving organic contamination. Here, we present a polymer-free transfer technique employing thin muscovite (mica) crystals. Temperature control over mica adhesion enables deterministic pick-up, stacking, and release of 2D materials, while their crystalline, inorganic nature ensures pristine interfaces and suppresses strain. Fully compatible with existing fabrication workflows, this approach enables the assembly of demanding vdW heterostructures, including those with exposed conductive layers, moiré superlattices and suspended membranes. Our method represents a promising strategy for vdW heterostructure fabrication toward its automatisation.
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