Truly chiral phonons in {\alpha}-HgS observed by circularly polarised Raman spectroscopy.

Chirality is a manifestation of the asymmetry inherent in nature. Chirality has been defined as the symmetry breaking of the parity of static objects, and the definition was extended to dynamic motion such that true and false chiralities were distinguished. Recently, rotating, yet not propagating, atomic motions were predicted and observed in two-dimensional materials, and they were referred to as "chiral phonons". A natural development would be the discovery of truly chiral phonons that propagate while rotating in three-dimensional materials. Here, we used circularly polarised Raman scattering and first-principles calculations to identify truly chiral phonons in chiral bulk crystals. This approach enabled us to determine the chirality of a crystal in a noncontact and nondestructive manner. In addition, we demonstrated that the law of the conservation of pseudoangular momentum holds between circularly polarised photons and chiral phonons. These findings are foreseen to pave the way for transferring the pseudoangular momentum from photons to electron spins via the propagating chiral phonons in opto-phononic-spintronic devices.