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Three-dimensional integration of two-dimensional field-effect transistors.

Darsith JayachandranRahul PendurthiMuhtasim Ul Karim SadafNajam U SakibAndrew PannoneChen ChenYing HanNicholas TrainorShalini KumariThomas V Mc KnightJoan Marie RedwingYang YangSaptarshi Das
Published in: Nature (2024)
In the field of semiconductors, three-dimensional (3D) integration not only enables packaging of more devices per unit area, referred to as 'More Moore' 1 but also introduces multifunctionalities for 'More than Moore' 2 technologies. Although silicon-based 3D integrated circuits are commercially available 3-5 , there is limited effort on 3D integration of emerging nanomaterials 6,7 such as two-dimensional (2D) materials despite their unique functionalities 7-10 . Here we demonstrate (1) wafer-scale and monolithic two-tier 3D integration based on MoS 2 with more than 10,000 field-effect transistors (FETs) in each tier; (2) three-tier 3D integration based on both MoS 2 and WSe 2 with about 500 FETs in each tier; and (3) two-tier 3D integration based on 200 scaled MoS 2 FETs (channel length, L CH  = 45 nm) in each tier. We also realize a 3D circuit and demonstrate multifunctional capabilities, including sensing and storage. We believe that our demonstrations will serve as the foundation for more sophisticated, highly dense and functionally divergent integrated circuits with a larger number of tiers integrated monolithically in the third dimension.
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