AI Article Synopsis
- Lithographically defined nanomagnet arrays, like artificial spin ice (ASI), are useful for applications in probabilistic computing and magnonics due to their unique magnetic dynamics and configurations.
- ASI arrays experience geometric frustration, leading to the formation of topologically protected magnetic charges called monopoles, which require careful manipulation to avoid affecting neighboring charges.
- By introducing ferromagnetic defects in the ASI lattice, the research allows for the controlled creation and movement of monopoles, paving the way for advanced applications like reconfigurable nanomagnonic devices.
Article Abstract
Lithographically defined arrays of nanomagnets are well placed for application in areas such as probabilistic computing or reconfigurable magnonics due to their emergent collective dynamics and writable magnetic order. Among them are artificial spin ice (ASI), which are arrays of binary in-plane macrospins exhibiting geometric frustration at the vertex interfaces. Macrospin flips in the arrays create topologically protected magnetic charges, or emergent monopoles, which are bound to an antimonopole to conserve charge. In the absence of controllable pinning, it is difficult to manipulate individual monopoles in the array without also influencing other monopole excitations or the counter-monopole charge. Here, we tailor the local magnetic order of a classic ASI lattice by introducing a ferromagnetic defect with shape anisotropy into the array. This creates monopole injection sites at nucleation fields below the critical lattice switching field. Once formed, the high energy monopoles are fixed to the defect site and may controllably propagate through the lattice under stimulation. Defect programing of bound monopoles within the array allows fine control of the pathways of inverted macrospins. Such control is a necessary prerequisite for the realization of functional devices, e. g. reconfigurable waveguide in nanomagnonic applications.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9233697 | PMC |
| http://dx.doi.org/10.1038/s41467-022-31309-0 | DOI Listing |
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Article Synopsis
- Lithographically defined nanomagnet arrays, like artificial spin ice (ASI), are useful for applications in probabilistic computing and magnonics due to their unique magnetic dynamics and configurations.
- ASI arrays experience geometric frustration, leading to the formation of topologically protected magnetic charges called monopoles, which require careful manipulation to avoid affecting neighboring charges.
- By introducing ferromagnetic defects in the ASI lattice, the research allows for the controlled creation and movement of monopoles, paving the way for advanced applications like reconfigurable nanomagnonic devices.
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