Techniques for transduction and storage of quantum level signals

What is claimed is: 1. A system for transducing and storing a qubit signal, comprising: a suspended crystalline transducer for converting the qubit signal between a microwave form and an acoustic form when the suspended crystalline transducer oscillates at a tuning frequency; and a suspended crystalline structure coupled to the suspended crystalline transducer, the suspended crystalline structure comprising a plurality of acoustic cavities chained together, wherein the acoustic cavities are of differing sizes to store the qubit signal in acoustic form when the suspended crystalline transducer oscillates at the tuning frequency wherein a plurality of suspended crystalline structures, disposed in a geometric design to isolate the qubit signal in acoustic form, surround the suspended crystalline transducer and the suspended crystalline structure. 2. The system for transducing the qubit signal of claim 1 , wherein the suspended crystalline transducer comprises a piezoelectric material overlay of a second suspended crystalline structure. 3. The system for transducing the qubit signal of claim 2 , wherein the piezoelectric material comprises Aluminum Nitride. 4. The system for transducing the qubit signal of claim 2 , further comprising: a plurality of conductors that are electrically coupled to the piezoelectric material overlay of the second suspended crystalline structure, wherein the plurality of conductors form an interleaved pattern and provide alternating polarity electrical signals to the piezoelectric material to generate an oscillation at the tuning frequency. 5. The system for transducing the qubit signal of claim 4 , wherein the plurality of conductors comprise aluminum. 6. The system for transducing the qubit signal of claim 1 , wherein: the suspended crystalline transducer comprises a second suspended crystalline structure and a plurality of conductors overlaying the second suspended crystalline structure; the plurality of conductors are configured to form a plurality of capacitive features; during transduction, the plurality of capacitive features oscillate at the tuning frequency to generate a changing capacitance; and the qubit signal in acoustic form is generated based on the changing capacitance. 7. The system for transducing the qubit signal of claim 1 , wherein the suspended crystalline transducer and the suspended crystalline structure each comprise silicon. 8. The system for transducing the qubit signal of claim 1 , wherein the suspended crystalline transducer and the suspended crystalline structure are disposed in a single crystal silicon layer of a silicon-on-insulator substrate. 9. The system for transducing the qubit signal of claim 1 , wherein the qubit signal is swapped between the suspended crystalline transducer and the suspended crystalline structure when the suspended crystalline transducer oscillates at the tuning frequency.