Optical excitation of magnons in an easy-plane antiferromagnet: Application to Sr2IrO4

We study the interaction of a (classical) light field with the magnetic degrees of freedom in the two-dimensional antiferromagnet Sr2IrO4. The reduced space group symmetry of the crystal allows for several channels for spin-operator bilinears to couple to the electric field. Integrating out high-energy degrees of freedom in a Keldysh framework, we derive induced effective fields, which enter the equations of motion of the low-energy mode of in-plane rotations, which couple to the out-of-plane magnetization. Considering a pump-probe protocol, these induced fields excite magnetization oscillations, which can subsequently be probed, e.g., using Kerr rotation. We discuss how the induced fields depend on polarization and frequency of the driving light, and our study applies to both resonant and nonresonant regimes. Crucially, the induced fields depend on the two-magnon density of states, thus allowing for further insight into properties of the magnetic excitation spectrum. Furthermore, these effects rely upon (weak) magnon interactions, and so are beyond a Floquet magnon description.