Direct observation of angular momentum transfer among crystal lattice modes (2503.11626v1)

Abstract: The discrete rotational symmetry of crystals leads to the conservation of quantized angular momentum in solids. While the exchange of energy and linear momentum between lattice vibrations (phonons) via anharmonic coupling is a cornerstone of solid-state physics, conservation and transfer of angular momentum within the lattice remains a postulate. Recently, phonon angular momentum, often in the form of chiral phonons, has been linked to giant magnetic fields, thermal Hall conductivity, dynamical multiferroicity, ultrafast demagnetization, or magnetic switching. However, the inherent process of phonon to phonon angular momentum transfer, fundamentally required to reach any magnetization equilibrium and imperative for all spin relaxation phenomena in solids, remains elusive. Here, we demonstrate the coherent transfer of angular momentum from one lattice mode to another by establishing helical nonlinear phononics. We directly observe rotational phonon-phonon Umklapp scattering dictated by pseudo angular momentum conservation and the threefold rotational symmetry of the topological insulator bismuth selenide. We identify nonlinear phonon-phonon coupling as an angular momentum transfer channel, confirmed by our ab-initio calculations. Besides bearing universal implications for angular momentum dissipation abundant in nature, our work actively reverses the natural flow, leading to the nonlinear upconversion of lattice angular momentum. We thus open the field of helical and chiral nonlinear phononics, representing a selective handle for ultrafast control of spins, topology and chiral quasi-particles.