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Main Authors: Nuzzi, Davide, Banchi, Leonardo, Vaia, Ruggero, Compagno, Enrico, Cuccoli, Alessandro, Verrucchi, Paola, Bose, Sougato
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2310.17422
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author Nuzzi, Davide
Banchi, Leonardo
Vaia, Ruggero
Compagno, Enrico
Cuccoli, Alessandro
Verrucchi, Paola
Bose, Sougato
author_facet Nuzzi, Davide
Banchi, Leonardo
Vaia, Ruggero
Compagno, Enrico
Cuccoli, Alessandro
Verrucchi, Paola
Bose, Sougato
contents The Toffoli gate is the essential ingredient for reversible computing, an energy efficient classical computational paradigm that evades the energy dissipation resulting from Landauer's principle. In this paper we analyze different setups to realize a magnetic implementation of the Toffoli gate using three interacting classical spins, each one embodying one of the three bits needed for the Toffoli gate. In our scheme, different control-spins configurations produce an effective field capable of conditionally flipping the target spin. We study what are the experimental requirements for the realization of our scheme, focusing on the degree of local control, the ability to dynamically switch the spin-spin interactions, and the required single-spin anisotropies to make the classical spin stable, showing that these are compatible with current technology.
format Preprint
id arxiv_https___arxiv_org_abs_2310_17422
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Full-magnetic implementation of a classical Toffoli gate
Nuzzi, Davide
Banchi, Leonardo
Vaia, Ruggero
Compagno, Enrico
Cuccoli, Alessandro
Verrucchi, Paola
Bose, Sougato
Quantum Physics
Mesoscale and Nanoscale Physics
Materials Science
Applied Physics
Chemical Physics
The Toffoli gate is the essential ingredient for reversible computing, an energy efficient classical computational paradigm that evades the energy dissipation resulting from Landauer's principle. In this paper we analyze different setups to realize a magnetic implementation of the Toffoli gate using three interacting classical spins, each one embodying one of the three bits needed for the Toffoli gate. In our scheme, different control-spins configurations produce an effective field capable of conditionally flipping the target spin. We study what are the experimental requirements for the realization of our scheme, focusing on the degree of local control, the ability to dynamically switch the spin-spin interactions, and the required single-spin anisotropies to make the classical spin stable, showing that these are compatible with current technology.
title Full-magnetic implementation of a classical Toffoli gate
topic Quantum Physics
Mesoscale and Nanoscale Physics
Materials Science
Applied Physics
Chemical Physics
url https://arxiv.org/abs/2310.17422