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Reversible optical control of magnetism in engineered artificial multiferroics.

Diego A OchoaEnric MenéndezJesús López SánchezAdolfo Del CampoZheng MaIrena SpasojevićIgnasi FinaJosé Francisco FernándezFernando Rubio-MarcosJordi SortJosé E García
Published in: Nanoscale (2024)
Optical means instead of electric fields may offer a new pathway for low-power and wireless control of magnetism, holding great potential to design next-generation memory and spintronic devices. Artificial multiferroic materials have shown remarkable suitability as platforms towards the optical control of magnetic properties. However, the practical use of magnetic modulation should be both stable and reversible and, particularly, it should occur at room temperature. Here we show an unprecedented reversible modulation of magnetism using low-intensity visible-light in Fe 75 Al 25 /BaTiO 3 heterostructures, at room temperature. This is enabled by the existence of highly oriented charged domain walls arranged in arrays of alternating in-plane and out-of-plane ferroelectric domains with stripe morphology. Light actuation yields a net anisotropic stress caused by ferroelectric domain switching, which leads to a 90-degree reorientation of the magnetic easy axis. Significant changes in the coercivity and squareness ratio of the hysteresis loops can be light-modulated, encouraging the development of novel low energy-consumption wireless magneto-optical devices.
Keyphrases
  • room temperature
  • high resolution
  • high speed
  • visible light
  • ionic liquid
  • molecularly imprinted
  • working memory
  • risk assessment
  • metal organic framework
  • stress induced