Tuning laser-induced terahertz spin currents from torque- to conduction-electron-mediated transport

Abstract

Spin transport is crucial for future spintronic devices operating at bandwidths up to the terahertz (THz) range. In F|N thin-film stacks of a ferro/ferrimagnetic layer F and a normal-metal layer N, spin transport is mediated by (1) spin-polarized conduction electrons and/or (2) torque between electron spins. To identify a cross-over from (1) to (2), we study laser-driven spin currents in F|Pt stacks where F is made of model materials with different degrees of electrical conductivity. For the magnetic insulators YIG, GIG and Maghemite, identical dynamics is observed. It arises from the THz interfacial spin Seebeck effect (SSE), is fully determined by the relaxation of the electrons in the metal layer and provides estimates of the spin-mixing conductance of the Maghemite/Pt interface. Remarkably, in the half-metallic ferrimagnet Fe3O4 (magnetite), our measurements reveal two spin-current components with opposite sign. The slower, positive component exhibits SSE dynamics and is assigned to torque-type magnon excitation of the A, B spin sublattices of Fe3O4. The faster, negative component arises from the pyro-spintronic effect and can consistently be assigned to ultrafast demagnetization of e-sublattice minority-spin hopping electrons. This observation supports the magneto-electronic model of Fe3O4. Our results provide a new route to the separation of torque- and conduction-electron-mediated spin currents