Different quantum systems, including rare-earth-ion-doped crystals, superconducting circuits, and spins in yttrium iron garnet (YIG) or diamond, have their unique type of quantum operation.
In a previous research, the team realized a tunable frequency conversion between microwave and photons utilizing the dynamical Faraday effect in a YIG microsphere.
However, both the implementation of cavity optomagnonics and most optomechanical systems have weaknesses, with the former having limited magneto-optical interaction strength while the latter demonstrating limited practical applications due to a lack of tunability.
In this research, the team developed a system consisting of an optomechanical cavity consisted of silica microsphere and a magnomechanical cavity consisted of YIG microsphere. Photons could be electrically manipulated through magnetostriction effect or optically manipulated through optical radiation pressure. Furthermore, photons in different microcavities could be coherently coupled through direct physical contact.
Based on the high quality optical measurement of the mechanical state of the system, researchers achieved a microwave-to-optical conversion with an ultrawide tuning range, far exceeding that of the previous magneto-optical single system.
In addition, the team observed a mechanical motion interference, in which the optically induced motion of the mechanical resonator is canceled by microwave-driven coherent motion.
In the future, this hybrid system that combines controlled phonons, magnons, and photons is expected to be applied in signal transduction and sensing.
