In molecular field-coupled nanocomputing, electrostatically-coupled molecules encode the logic information in their charge distribution, promising extremely low power consumption, room temperature operation, and THz frequency operations. Besides the impressive theoretical predictions and simulation confirmations, a working prototype must still be fabricated. This work discusses the most crucial aspects that hinder the fabrication of a working prototype and defines a roadmap to address and guide the procedure to fabricate a working proof of concept. Accurate physical simulations support each point of the roadmap.

A Roadmap for Molecular Field-Coupled Nanocomputing Actualization / Ravera, Federico; Beretta, Giuliana; Ardesi, Yuri; Krzywiecki, Maciej; Graziano, Mariagrazia; Piccinini, Gianluca. - ELETTRONICO. - (2023), pp. 212-213. (Intervento presentato al convegno 2023 IEEE Nanotechnology Materials and Devices Conference (NMDC) tenutosi a Paestum (IT) nel 22-25 October 2023) [10.1109/NMDC57951.2023.10344189].

A Roadmap for Molecular Field-Coupled Nanocomputing Actualization

Ravera, Federico;Beretta, Giuliana;Ardesi, Yuri;Graziano, Mariagrazia;Piccinini, Gianluca
2023

Abstract

In molecular field-coupled nanocomputing, electrostatically-coupled molecules encode the logic information in their charge distribution, promising extremely low power consumption, room temperature operation, and THz frequency operations. Besides the impressive theoretical predictions and simulation confirmations, a working prototype must still be fabricated. This work discusses the most crucial aspects that hinder the fabrication of a working prototype and defines a roadmap to address and guide the procedure to fabricate a working proof of concept. Accurate physical simulations support each point of the roadmap.
2023
979-8-3503-3546-0
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2984685