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On the Possibility of Reversible Magnonic Logic Gates

We propose and develop a concept of magnonic logic gates enabling reversible computing. The gates consist of passive elements: waveguides, cross-junctions and phase shifters. Logical 0 and 1 are encoded in the relative phase of the propagating spin wave packets (0 or π). The gates contain several possible trajectories for each packet to propagate from the input to the output. Re-direction of the spin wave packets among the possible trajectories is due to the interference in the magnetic cross-junctions. Two wave packets coming to the cross-junction in-phase propagate through the junction without reflection. Two packets coming out-of-phase to the junction are completely reflected back. The operation of the cross-junction is illustrated by numerical modeling. We estimate the power dissipation in the proposed circuits and the feasibility of cascading such magnetic devices in large circuits. The proposed gates may potentially provide a route to magnetic reversible logic circuitry with power dissipation less than kT per operation.

preprint2013arXivOpen access
Alexander Khitun
cond-mat.mes-hallquant-ph
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Alexander Khitun

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