APL Materials (Feb 2024)

Imaging the magnetic nanowire cross section and magnetic ordering within a suspended 3D artificial spin-ice

  • Edward Harding,
  • Tohru Araki,
  • Joseph Askey,
  • Matthew Hunt,
  • Arjen Van Den Berg,
  • David Raftrey,
  • Lucia Aballe,
  • Burkhard Kaulich,
  • Emyr MacDonald,
  • Peter Fischer,
  • Sam Ladak

DOI
https://doi.org/10.1063/5.0176907
Journal volume & issue
Vol. 12, no. 2
pp. 021116 – 021116-10

Abstract

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Artificial spin-ice systems are patterned arrays of magnetic nanoislands arranged into frustrated geometries and provide insight into the physics of ordering and emergence. The majority of these systems have been realized in two-dimensions, mainly due to the ease of fabrication, but with recent developments in advanced nanolithography, three-dimensional artificial spin ice (ASI) structures have become possible, providing a new paradigm in their study. Such artificially engineered 3D systems provide new opportunities in realizing tunable ground states, new domain wall topologies, monopole propagation, and advanced device concepts, such as magnetic racetrack memory. Direct imaging of 3DASI structures with magnetic force microscopy has thus far been key to probing the physics of these systems but is limited in both the depth of measurement and resolution, ultimately restricting measurement to the uppermost layers of the system. In this work, a method is developed to fabricate 3DASI lattices over an aperture using two-photon lithography, thermal evaporation, and oxygen plasma exposure, allowing the probe of element-specific structural and magnetic information using soft x-ray microscopy with x-ray magnetic circular dichroism (XMCD) as magnetic contrast. The suspended polymer–permalloy lattices are found to be stable under repeated soft x-ray exposure. Analysis of the x-ray absorption signal allows the complex cross section of the magnetic nanowires to be reconstructed and demonstrates a crescent-shaped geometry. Measurement of the XMCD images after the application of an in-plane field suggests a decrease in magnetic moment on the lattice surface due to oxidation, while a measurable signal is retained on sub-lattices below the surface.