Theory of ac magnetoelectric transport in normal-metal $-$ magnetic-insulator heterostructures

Electron-magnon coupling at the interface between a normal metal and a magnetically ordered insulator modifies the electrical conductivity of the normal metal, an effect known as spin-Hall magnetoresistance. It can also facilitate magnon-mediated current drag, the nonlocal electric current response of two normal metal layers separated by a magnetic insulator. In this article, we present a theory of these two spintronic effects and their nonlinear counterparts for time-dependent applied electric fields $E(\omega)$, with driving frequencies $\omega$ up to the THz regime. We compare various mechanisms leading to a quadratic-in-$E$ response $-$ Joule heating, spin-torque diode effect, and magnonic unidirectional spin-Hall magnetoresistance $-$ and show how these can be disentangled by their characteristic dependences on $\omega$ and the magnetization direction.