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Wavelength transduction from a 3D microwave cavity to telecom using piezoelectric optomechanical crystals

Hugh Ramp, Thomas J. Clark, Bradley Hauer, C. Doolin, Krishna C. Balram, Kartik Srinivasan, J. P. Davis

2020Applied Physics Letters22 citationsDOIOpen Access PDF

Abstract

Microwave-to-optical transduction has received a great deal of interest from the cavity optomechanics community as a landmark application for electro-optomechanical systems. In this Letter, we demonstrate a novel transducer that combines high-frequency mechanical motion and a microwave cavity for the first time. The system consists of a 3D microwave cavity and a gallium arsenide optomechanical crystal, which has been placed in the microwave electric field maximum. This allows the microwave cavity to actuate the gigahertz-frequency mechanical breathing mode in the optomechanical crystal through the piezoelectric effect, which is then read out using a telecom optical mode. The gallium arsenide optomechanical crystal is a good candidate for low-noise microwave-to-telecom transduction, as it has been previously cooled to the mechanical ground state in a dilution refrigerator. Moreover, the 3D microwave cavity architecture can naturally be extended to couple to superconducting qubits and to create hybrid quantum systems.

Topics & Concepts

MicrowavePiezoelectricityWavelengthOptoelectronicsMaterials scienceTransduction (biophysics)OpticsTelecommunicationsPhysicsAcousticsChemistryEngineeringBiochemistryMechanical and Optical ResonatorsAdvanced MEMS and NEMS TechnologiesPhotonic and Optical Devices
Wavelength transduction from a 3D microwave cavity to telecom using piezoelectric optomechanical crystals | Litcius