Local heat emission due to unidirectional spin-wave heat conveyer effect observed by lock-in thermography

Lock-in thermography measurements were performed to reveal heat source distribution induced by the unidirectional spin-wave heat conveyer effect (USHCE) of magnetostatic surface spin waves. When the magnetostatic surface spin waves are excited in an yttrium iron garnet slab, the lock-in thermography images show spatially biased sharp and complicated heating patterns, indicating the importance of edge spin-wave dynamics for USHCE. The accessibility to the local heat emission properties allows us to clarify a capability of remote heating realized by USHCE; it can transfer energy for heating even through a macro-scale air gap between two magnetic materials owing to the long-range dipole-dipole coupling.

Automated summary

Lock-in thermography measurements were used to study heat source distribution induced by the unidirectional spin-wave heat conveyer effect, showing spatially biased sharp heating patterns and the importance of edge spin-wave dynamics. The capability of remote heating through a macro-scale air gap between two magnetic materials was demonstrated thanks to long-range dipole-dipole coupling.