Periodic Reporting for period 2 - ExCOM-cCEO (Extremely Coherent Mechanical Oscillators and circuit Cavity Electro-Optics)
Periodo di rendicontazione: 2021-04-01 al 2022-09-30
To advance the state of the art in superconducting electromechanical devices, we developed a novel nanofabrication process that allows us to fabricate ultracoherent mechanical resonators for superconducting circuits. Within the first year of the project, we purchased and installed a new cryogenic dilution fridge funded by ERC project. This fridge provides environment temperature of 8 mK that results in two times higher quality factors than in our old system. We characterized the new devices using this fridge and measured the record of 18 million mechanical quality factor for a superconducting electromechanical system. We successfully performed quantum ground state cooling of the mechanical motion and measured 0.1 quanta occupation of mechanical motion. We established a time-domain experimental setup to conduct pulse sequential measurements on this device and currently are improving the efficiency of this approach. The consistent and reproducible fabrication process we developed allowed us to make multimode circuits of electromechanical systems where we can explore topological physics.
To pursue our goal of transducing quantum information from the microwave domain to the optical domain, we developed a new method to optically readout superconducting circuits via light. The cryogenic electro-optical interconnect exploited a commercial optical phase modulator to transduce microwave signals to light at 800 milliKelvin temperatures. Operation at optical frequencies allows long range transmission of information in optical fibers. To improve the performance of our transducer, we have analysed and proposed a new kind of device harnessing the strong piezoelectric coupling of microwave signals to a mechanical excitation: a high overtone bulk acoustic resonance (HBAR), parametrically interacting with optical supermodes of optically coupled ring cavities to realize (quantum) coherent microwave-optical conversion. We also developed an ultra-low loss hybrid lithium niobate and silicon nitride integrated photonic platform. We used wafer bonding to combine the low-loss waveguiding of our silicon nitride PICs with electro-optic properties of lithium niobate.
Our progress in electro-optomechanics has allowed us to realize orders of magnitude longer coherence times and we can now study the time domain dynamics of mechanical systems in the quantum regime. This system combines the sensitivity of high-Q mechanics with the power of quantum electrodynamics techniques in superconducting circuits. We are now working towards hybrid systems which couple superconducting qubits to mechanical resonators. The long coherence times of our mechanical system may allow it to serve as a long-lived quantum memory.
The current quantum computing paradigm with superconducting qubits supports only a limited number of qubits due to the constraints of current dilution refrigerator technology. There is therefore a need to transmit quantum information from these circuits. However, quantum information cannot be encoded in the microwave domain at room temperature. One way to circumvent this constraint is to encode the information in the optical domain, which we are aiming to do with our new platforms for microwave-to-optical conversion. Achieving this goal would also enable coupling of superconducting qubits to other quantum systems, which could bring forth a new generation of quantum computers that combine the advantages of competing quantum processing methods.
All data and experimental details of our publications are available on public repositories and libraries such as ZENODO (https://zenodo.org/) and arXiv (https://arxiv.org/). In addition, our group has developed a new platform for collecting and sharing the details of nanofabrication processes (https://nanofab-net.org/) from tacit knowledge in the field. This comprises a collection of notes that will significantly reduce the time and resources spent in nanofabrication facilities. This initiative upholds a culture of Open Science leading to higher transparency between the researchers and public society as well as increasing the reliability and reproducibility of our research.