Coherent oscillation between phonons and magnons

Consider observing two different waves with the same frequency and wavelength. When these waves are coupled, the amplitude alternates between the two waves periodically, a phenomenon called coherent beating oscillation. Such phenomena can be seen in familiar coupled pendulums and, on a cosmic scale, neutrino oscillations: the oscillation between different types of neutrinos. In solids, on the other hand, there are various wave excitations responsible for their thermal and electromagnetic properties. Here we report the observation of coherent beating between different excitation species in a solid: phonons and magnons. By using time-resolved magneto-optical microscopy, magnons generated in Lu2Bi1Fe3.4Ga1.6O12 gradually disappear by transforming to phonons, and after a while, they return to magnons. The period of the oscillation as a function of the field is consistent with the prediction of the magnon-phonon beating. The experimental results pave a way to coherent control of magnon-phonon systems in solids. In the field of spintronics, coherent control of propagating magnons is considered a promising mechanism for information processing. Here, strong coupling between magnons and phonons in lutetium iron garnet gives rise to long-lived coherent beating.

Automated summary

This study reports the observation of coherent beating between phonons and magnons in a solid material. By using time-resolved magneto-optical microscopy, the researchers were able to observe the transition between phonons and magnons in Lu2Bi1Fe3.4Ga1.6O12. The experimental results provide a way for coherent control of magnon-phonon systems in solids, which is considered promising for information processing in the field of spintronics.