Abstract
We present a comparative study of the spin wave properties in two magnetic films patterned into an artificial square spin ice-like geometry. The array elements are rectangular islands with the same lateral dimensions but with different thicknesses: 10 nm and 30 nm. Using Brillouin light scattering, the frequencies of spin wave excitations were measured as a function of the magnetic field going from positive to negative saturation. We find substantial changes with thickness to spin wave mode frequencies and the number of detected modes. Frequencies of spin waves localized at element edges are observed to evolve non-monotonically with magnetic fields and soften at critical fields. These critical fields enable us to extract information of the magnetization reversal of individual islands within the array. Finally, we discuss the effects of separation between islands and examine the possibilities for dynamic coupling through the overlap of collective edge modes.
Highlights
Patterning of ferromagnetic films into closely spaced, single domain islands can be used to create arrays of mesoscopic magnets often termed artificial spin ice (ASI).[1]
We present a comparative study of the spin wave properties in two magnetic films patterned into an artificial square spin ice-like geometry
We find substantial changes with thickness to spin wave mode frequencies and the number of detected modes
Summary
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