Speaker
Description
Magnonics is a concept using magnons - the collective excitation quanta of the spin system in magnetically ordered materials - as carriers for information. Magnons are waves of the electrons’ spin precessional motion. They propagate without charge transport and its associated Ohmic losses, paving the way for a substantial reduction of energy consumption in computers.
The full potential of magnonics lies in the combination of magnons with nano-sized spin textures. Both magnons and spin textures share a common ground set by the interplay of dipolar, spin-orbit and exchange energies rendering them perfect interaction partners. Magnons are fast, sensitive to the spins’ directions and easily driven far from equilibrium. Spin textures are robust, non-volatile and still reprogrammable on ultrashort timescales.
I will give an introduction about magnon propagation and manipulation in microstructures with non-collinear spin textures, in particular magnons propagating in nano channels formed by magnetic domain walls. Furthermore, I will address how magnons can be excited in domain wall channels by pure spin currents originating from the spin Hall effect and nonlinear effect in magnetic vortices.
References:
[1] K. Schultheiss, R. Verba, F. Wehrman et al.
Phys. Rev. Lett. 122, 097202 (2019)
[2] K. Wagner, A. Kákay, K. Schultheiss et al.
Nature Nanotech 11, 432 (2016).
[3] K. Vogt, F. Y. Fradin, J. E. Pearson, et al.
Nat Comms 5, 3727 (2014).
