Litcius/Paper detail

Low-power continuous-wave all-optical magnetic switching in ferromagnetic nanoarrays

Kilian D. Stenning, Xiaofei Xiao, Holly H. Holder, Jack C. Gartside, Alex Vanstone, Oscar W. Kennedy, Rupert F. Oulton, W. R. Branford

2023Cell Reports Physical Science17 citationsDOIOpen Access PDF

Abstract

All-optical magnetic switching promises ultrafast magnetization control without a magnetic field. Existing schemes typically require power-hungry femtosecond-pulsed lasers and complex magnetic materials. Here, we demonstrate deterministic, all-optical magnetic switching in simple ferromagnetic nanomagnets (Ni81Fe19, Ni50Fe50) with sub-diffraction limit dimensions using a focused low-power, linearly polarized continuous-wave laser. Isolated nanomagnets are switched across a range of dimensions, laser wavelengths, and powers. All square-geometry artificial spin ice vertex configurations are written at low powers (2.74 mW). Usually, switching with linearly polarized light is symmetry forbidden; here, the laser spot has a similar size to the nanomagnets, producing an absorption distribution that depends on the nanoisland-spot displacement. We attribute the deterministic switching to the transient dynamics of this asymmetric absorption. No switching is observed in Co or Ni nanostructures, suggesting the multi-species nature of NiFe plays a role. These results usher in inexpensive, low-power, optically controlled devices with impact across data storage, neuromorphic computation, and reconfigurable magnonics.

Topics & Concepts

NanomagnetUltrashort pulseLaserMaterials scienceFemtosecondOpticsMagnonicsSwitching timeFerromagnetismMetamaterialMagnetic fieldSpin waveOptoelectronicsCondensed matter physicsPhysicsMagnetizationSpin polarizationElectronSpin Hall effectQuantum mechanicsNeural Networks and Reservoir ComputingMagneto-Optical Properties and ApplicationsMagnetic properties of thin films