Scientists at the University of Manchester have discovered that placing magnetic films on atomically thin molybdenum disulfide (MoS₂) fundamentally changes how they lose energy, a finding that could bring 2D‑material spintronics a step closer to real devices. The team found that growing a widely used magnetic alloy, permalloy, on ultra‑thin MoS₂ alters the film’s internal crystal structure, changing how and where energy is lost as magnetic spins move. By separating energy losses that occur at the surface of the film from those arising within its internal structure, the researchers provide new design insights for devices that use two‑dimensional (2D) materials to control magnetism more efficiently.
Crucially, the work uses large‑area, manufacturing‑compatible MoS₂, showing that these effects are not confined to laboratory‑scale samples but are relevant for real, scalable spintronic technologies. The study, published in Physical Review Applied, demonstrates that transition‑metal dichalcogenides (TMDs) can alter the fundamental properties of magnetic films. The results highlight the importance of careful comparison with control materials when assessing the impact of 2D layers on magnetic behavior.
Spintronics is an alternative to conventional electronics that uses not only the charge of electrons, but also their spin, to store and process information. This approach underpins emerging technologies for magnetic memory and has potential applications in energy‑efficient, high‑speed computing. A major challenge in spintronics, however, is energy loss: as magnetic spins move, some energy is inevitably dissipated as heat, limiting device speed and efficiency.
