Process integration and future outlook of 2D transistors

Kevin O’Brien; Carl H. Naylor; C. J. Dorow; K. Maxey; Ashish Verma Penumatcha; Andrey Vyatskikh; Ting Zhong; A. Kitamura; Sudarat Lee; Carly Rogan; Wouter Mortelmans; Mahmut S. Kavrik; Rachel C. Steinhardt; Pratyush Buragohain; Sourav Dutta; Tristan A. Tronic; Scott B. Clendenning; P. Fischer; E. Steve Putna; M. Radosavljević; Matt Metz; Uygar E. Avci

doi:10.1038/s41467-023-41779-5

Process integration and future outlook of 2D transistors

Kevin O’Brien(Intel (United States)), Carl H. Naylor(Intel (United States)), C. J. Dorow(Intel (United States)), K. Maxey(Intel (United States)), Ashish Verma Penumatcha(Intel (United States)), Andrey Vyatskikh(Intel (United States)), Ting Zhong(Intel (United States)), A. Kitamura(Intel (United States)), Sudarat Lee(Intel (United States)), Carly Rogan(Intel (United States)), Wouter Mortelmans(Intel (United States)), Mahmut S. Kavrik(Intel (United States)), Rachel C. Steinhardt(Intel (United States)), Pratyush Buragohain(Intel (United States)), Sourav Dutta(Intel (United States)), Tristan A. Tronic(Intel (United States)), Scott B. Clendenning(Intel (United States)), P. Fischer(Intel (United States)), E. Steve Putna(Intel (United States)), M. Radosavljević(Intel (United States)), Matt Metz(Intel (United States)), Uygar E. Avci(Intel (United States))

Nature Communications

October 12, 2023

10.1038/s41467-023-41779-5

Cited by 125Open Access

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Abstract

The academic and industrial communities have proposed two-dimensional (2D) transition metal dichalcogenide (TMD) semiconductors as a future option to supplant silicon transistors at sub-10nm physical gate lengths. In this Comment, we share the recent progress in the fabrication of complementary metal-oxide-semiconductor (CMOS) devices based on stacked 2D TMD nanoribbons and specifically highlight issues that still need to be resolved by the 2D community in five crucial research areas: contacts, channel growth, gate oxide, variability, and doping. While 2D TMD transistors have great potential, more research is needed to understand the physical interactions of 2D materials at the atomic scale. 2D semiconductors have been proposed as a potential option to replace or complement silicon electronics at the nanoscale. Here, the authors discuss the recent progress and remaining challenges that need to be addressed by the academic and industrial research communities towards the commercialization of 2D transistors.

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