Applications of a superconducting device that mixes surface acoustic waves and microwave signals

What is claimed is: 1. A method, comprising: receiving, by a microwave Josephson mixer, and from a superconducting surface acoustic wave resonator of a superconducting device, a surface acoustic wave signal that comprises one or more phonons that resonate at a first frequency; receiving, by the microwave Josephson mixer and from a superconducting microwave resonator of the superconducting device, a microwave signal that comprises one or more photons that resonate at a second frequency; and mixing, by the microwave Josephson mixer, the surface acoustic wave signal and the microwave signal based on a microwave control signal received from a microwave source operatively coupled to the microwave Josephson mixer. 2. The method of claim 1 , further comprising: transferring, by the microwave Josephson mixer, quantum information from the superconducting surface acoustic wave resonator to the superconducting microwave resonator based on an application of pump drive applied at a frequency difference between the microwave signal and the surface acoustic wave signal. 3. The method of claim 1 , further comprising: transferring, by the microwave Josephson mixer, quantum information from the superconducting microwave resonator to the superconducting surface acoustic wave resonator based on an application of a pump drive applied at a frequency difference between the surface acoustic wave signal and the microwave signal. 4. The method of claim 1 , further comprising: transferring, based on the microwave control signal received by the microwave Josephson mixer, a first quantum information from the superconducting surface acoustic wave resonator to the superconducting microwave resonator and second quantum information from the superconducting microwave resonator to the superconducting surface acoustic wave resonator. 5. The method of claim 1 , further comprising: disconnecting, by the microwave Josephson mixer, a connection between the superconducting surface acoustic wave resonator and the superconducting microwave resonator based on determining that the mixing of the surface acoustic wave signal and the microwave signal is to be stopped. 6. The method of claim 5 , further comprising: reenabling, by the microwave Josephson mixer, the connection between the superconducting surface acoustic wave resonator and the superconducting microwave resonator based on determining that the mixing of the surface acoustic wave signal and the microwave signal is to be restarted. 7. The method of claim 1 , further comprising: transferring, by the microwave Josephson mixer, a first portion of quantum information between the superconducting surface acoustic wave resonator and the superconducting microwave resonator based on a first power of the microwave control signal; and transferring, by the microwave Josephson mixer, a second portion of quantum information between the superconducting surface acoustic wave resonator and the superconducting microwave resonator based on a second power of the microwave control signal. 8. The method of claim 1 , wherein the mixing the surface acoustic wave signal and the microwave signal comprises transducing information carried by the surface acoustic wave signal into the microwave signal in a unitary manner. 9. The method of claim 1 , wherein the mixing the surface acoustic wave signal and the microwave signal comprises transducing information carried by the microwave signal into the surface acoustic wave signal in a unitary manner. 10. A method, comprising: receiving, at a frequency converter, and from a superconducting surface acoustic wave resonator, a surface acoustic wave signal that comprises one or more phonons that resonate at a first frequency; receiving, at the frequency converter and from a superconducting microwave resonator, a microwave signal that comprises one or more photons that resonate at a second frequency; and implementing, by the frequency converter, a lossless frequency conversion between first information of the superconducting surface acoustic wave resonator and second information of the superconducting microwave resonator based on a pump signal received from a microwave source. 11. The method of claim 10 , wherein the implementing the lossless frequency conversion comprises: mapping, by the frequency converter, a propagating radio frequency signal to a phononic mode in the superconducting surface acoustic wave resonator; and upconverting, by the frequency converter, the phononic mode to a photonic mode in the superconducting microwave resonator via an application of a microwave control signal with a defined frequency, wherein the upconverting of the phononic mode is enabled by a lossless three-wave mixing interaction, and wherein an upconverted microwave signal propagates upon leaving the superconducting microwave resonator. 12. The method of claim 11 , wherein a first value of a microwave control signal frequency is equal to an absolute value of a frequency difference between a resonance frequency of the superconducting microwave resonator and the superconducting surface acoustic wave resonator. 13. The method of claim 10 , wherein the implementing the lossless frequency conversion comprises: mapping, by the frequency converter, a propagating microwave frequency signal to a photonic mode in the superconducting microwave resonator; and downconverting, by the frequency converter, the photonic mode to a phononic mode in the superconducting surface acoustic wave resonator via an application of a microwave control signal with a defined frequency, wherein the downconverting of the photonic mode is enabled by a lossless three-wave mixing interaction, and wherein a downconverted surface acoustic wave signal propagates upon leaving the superconducting surface acoustic wave resonator. 14. The method of claim 10 , further comprising: transferring, by the frequency converter, information from the superconducting surface acoustic wave resonator to the superconducting microwave resonator based on a frequency and an amplitude of a microwave control signal. 15. The method of claim 14 , wherein the information comprises quantum information. 16. The method of claim 10 , further comprising: transferring, by the frequency converter, information from the superconducting microwave resonator to the superconducting surface acoustic wave resonator based on a frequency and an amplitude of a microwave control signal. 17. A method, comprising: amplifying, by a Josephson parametric amplifier, first quadratures of a surface acoustic wave signal entering a first port of a device and second quadratures of a microwave signal entering a second port of the device; and outputting, by the Josephson parametric amplifier, and through a first output port, a first amplified signal that comprises a first output signal and a first transmitted signal with frequency conversion and, through a second output port, a second amplified signal that comprises a second output signal and a second transmitted signal with frequency conversion. 18. The method of claim 17 , wherein the first output signal comprises a first same-frequency signal reflecting off the first port and the first transmitted signal comprises a first frequency-converted signal transmitted to the first port from the second port, and wherein the second output signal comprises a second same-frequency signal reflecting off the second port and the second transmitted signal comprises a second frequency-converted signal transmitted to the second port from the first port. 19. The m