Dynamical renormalisation of a spin Hamiltonian via high-order nonlinear magnonics

The macroscopic magnetic order in the ground state of solids is determined by the spin-dependent Hamiltonian of the system. In the absence of external magnetic fields, this Hamiltonian contains the exchange interaction, which is of electrostatic origin, and the spin-orbit coupling, whose magnitude depends on the atomic charge. Spin-wave theory provides a representation of the entire spectrum of collective magnetic excitations, called magnons, assuming the interactions to be constant and the number of magnons in the system negligible. However, the electric field component of light is able to perturb electrostatic interactions, charge distributions and, at the same time, can create a magnon population. A fundamental open question therefore concerns the possibility to optically renormalise the spin Hamiltonian. Here, we test this hypothesis by using femtosecond laser pulses to resonantly pump electric-dipole-active pairs of high-energy magnons near the edges of the Brillouin zone. The transient spin dynamics reveals the activation and a surprising amplification of coherent low-energy zone-centre magnons, which are not directly driven. Strikingly, the spectrum of these low-energy magnons differs from the one observed in thermal equilibrium, the latter being consistent with spin-wave theory. The light-spin interaction thus results in a room-temperature renormalisation of the magnetic Hamiltonian, with an estimated modification of the magnetic interactions by 10% of their ground-state values. We rationalise the observation in terms of a novel resonant scattering mechanism, in which zone-edge magnons couple nonlinearly to the zone-centre modes. In a quantum mechanical model, we analytically derive the corrections to the spectrum due to the photo-induced magnon population, which are consistent with our experiments. Our results present a milestone for an all-optical engineering of Hamiltonians.