Local inhomogeneities enable phase-dependent non-adiabatic parametric amplification of propagating spin waves in YIG nanostructures via momentum scattering, as shown by micromagnetic simulations and Brillouin light scattering experiments.
Experimental prototype of a spin-wave majority gate
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abstract
Featuring low heat dissipation, devices based on spin-wave logic gates promise to comply with increasing future requirements in information processing. In this work, we present the experimental realization of a majority gate based on the interference of spin waves in an Yttrium-Iron-Garnet-based waveguiding structure. This logic device features a three-input combiner with the logic information encoded in the phase of the spin waves. We show that the phase of the output signal represents the majority of the phase of the input signals. A switching time of about 10 ns in the prototype device provides evidence for the ability of sub-nanosecond data processing in future down-scaled devices.
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cond-mat.other 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Phase-dependent parametric amplification of propagating spin waves in YIG nanostructures enabled by local inhomogeneities
Local inhomogeneities enable phase-dependent non-adiabatic parametric amplification of propagating spin waves in YIG nanostructures via momentum scattering, as shown by micromagnetic simulations and Brillouin light scattering experiments.