Periodic and Aperiodic NiFe Nanomagnet/Ferrimagnet Hybrid Structures for 2D Magnon Steering and Interferometry with High Extinction Ratio

Magnons, quanta of spin waves, are known to enable information processing with low power consumption at the nanoscale. So far, however, experimentally realized half-adders, wave-logic, and binary output operations are based on few & mu;m-long spin waves and restricted to one spatial direction. Here, magnons with wavelengths & lambda; down to 50 nm in ferrimagnetic Y3Fe5O12 below 2D lattices of periodic and aperiodic ferromagnetic nanopillars are explored. Due to their high rotational symmetries and engineered magnetic resonances, the lattices allow short-wave magnons to propagate in arbitrarily chosen on-chip directions when excited by conventional coplanar waveguides. Performing interferometry with magnons over macroscopic distances of 350 x & lambda; without loss of coherency, unprecedentedly high extinction ratios of up to 26 (& PLUSMN;8) dB [31 (& PLUSMN;2) dB] for a binary 1/0 output operation at & lambda; = 69 nm (& lambda; = 154 nm) are achieved in this work. The reported findings and design criteria for 2D magnon interferometry are particularly important in view of the realization of complex neuronal networks recently proposed for interfering spin waves underneath nanomagnets.

Automated summary

Researchers investigate magnons with wavelengths down to 50 nm in ferrimagnetic Y3Fe5O12 beneath 2D lattices and achieve magnon interferometry with high extinction ratios of up to 26 dB over macroscopic distances of 350 wavelengths. These findings are important for the realization of complex neuronal networks.