Large-area synthesis and transfer of multilayer hexagonal boron nitride for enhanced graphene device arrays Article Swipe

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Satoru Fukamachi , Pablo Solís‐Fernández , Kenji Kawahara , Daichi Tanaka , Toru Otake , Yung‐Chang Lin , Kazu Suenaga , Hiroki Ago ·

YOU? · · 2023 · Open Access · · DOI: https://doi.org/10.1038/s41928-022-00911-x · OA: W4319312466

Multilayer hexagonal boron nitride (hBN) can be used to preserve the intrinsic physical properties of other two-dimensional materials in device structures. However, integrating the material into large-scale two-dimensional heterostructures remains challenging due to the difficulties in synthesizing high-quality large-area multilayer hBN and combining it with other two-dimensional material layers of the same scale. Here we show that centimetre-scale multilayer hBN can be synthesized on iron–nickel alloy foil by chemical vapour deposition, and then used as a substrate and as a surface-protecting layer in graphene field-effect transistors. We also develop an integrated electrochemical transfer and thermal treatment method that allows us to create high-performance graphene/hBN heterostacks. Arrays of graphene field-effect transistors fabricated by conventional and scalable methods show an enhancement in room-temperature carrier mobility when hBN is used as an insulating substrate, and a further increase—up to a value of 10,000 cm 2 V −1 s −1 —when graphene is encapsulated with another hBN sheet.