AFRL measures first superconducting quantum bits (qubit), first-ever demo for a DOD service lab
A cryogenic refrigerator installed in the Quantum Information and Sciences Laboratory at AFRL’s Information Directorate in Rome, New York. The device is used by AFRL researchers to measure the energy and coherence times of superconducting quantum bits (qubits), two important characteristics that determine how long qubits can retain quantum information. (Courtesy photo)
Researchers at the Air Force Research Laboratory Information Directorate here have measured the energy relaxation and coherence times of superconducting quantum bits (qubits), two important characteristics that determine how long qubits can retain quantum information.
This achievement is an important milestone toward AFRL’s objective of developing and adapting quantum technologies for quantum networking and quantum information processing.
Critically, researchers here observed the coherence times to be in excess of 0.2 milli-seconds, on par with state-of-the art superconducting quantum processors operating in industry and the academic community, and indicative of exquisite cryogenic microwave engineering capabilities at AFRL which will be applied to develop quantum-networking capabilities.
The use of quantum systems – e.g. superconducting qubits, photons, and trapped-ions – for the dissemination of information has the potential to bring about transformative changes to timing, sensing, networking, and computing. In particular, utilization of quantum phenomena like entanglement and teleportation in communication networks could enable an array of new capabilities that would confer numerous advantages to the Air Force and the warfighter such as tamper-proof communication, quantum cloud computing, and distributed quantum sensing for enhanced precision in position, navigation, and timing applications, to name a few. In fact, to maximize versatility and functionality of such quantum networks, AFRL researchers are working to integrate multiple leading qubit modalities, each with its own respective functional advantage, into a heterogeneous quantum-networking platform. The demonstration of a superconducting qubit capability at AFRL is thus the latest addition to a quantum technology portfolio that includes state-of-the-art efforts in trapped-ions, integrated photonics, and cold atoms.
The behavior of superconducting qubits derives directly from the quantum phenomenon of superconductivity – the extinction in metals of electrical resistance and magnetic fields – in carefully engineered microcircuits. This behavior occurs at very low temperatures, thousandths of a degree above absolute zero. Thus, the operation of superconducting qubits requires the use of sophisticated apparatuses known as cryostats that cool the microcircuits and facilitate their transition to the quantum regime.
AFRL researchers installed and commissioned their first such cryostat in March 2020, though, this was just the first step toward measuring and manipulating superconducting qubits. Over the subsequent months, researchers here worked to install the myriad hardware components and electrical devices required for measuring the qubits and protecting them from ambient sources of noise; these included multiple stages of sensitive cryogenic microwave amplifiers, a nested series of shields to screen ambient electric and magnetic fields, and specialized instrumentation for the application and acquisition of the microwave signals used to probe and control the superconducting qubits. Notably, the results of this effort constituted the first measurements of superconducting qubits in a DoD service laboratory in early October 2020.
From here, AFRL Information Directorate researchers are undertaking three main research thrusts involving superconducting qubits in support of the broader objective to develop the building blocks of a heterogeneous quantum network. One path involves the development of superconducting processing modules and investigations of how to efficiently encode and decode information with such modules in a multi-node network; a second project seeks to develop hardware for converting quantum information between optical photonic qubits and superconducting qubits in order to have the ability to distribute quantum information over long distances using optical fibers; and a third effort is focused on integrating superconducting systems with trapped-ion quantum processors in order to combine the long quantum memory of trapped-ions with the rapid gate speed of superconducting qubits in a single platform. These are all outstanding challenges in the quantum information science community, and researchers here are uniquely poised to provide impactful solutions to them.
The superconducting qubit test chip was manufactured and initially measured at Massachusetts Institute of Technology Lincoln Laboratory (MIT-LL) to serve as a calibration benchmark for the Information Directorate’s cryostat and microwave infrastructure. Measurements performed by AFRL researchers demonstrated qubit performance on the directorate’s cryostat that matched the performance observed by researchers at MIT-LL. Such benchmarking thus provides confirmation of the integrity of AFRL’s cryostat, microwave circuitry, lab environment, and measurement techniques. In addition, it establishes the robustness of the superconducting qubits to distribution between research facilities.
AFRL’s Dr. Matt LaHaye and Dr. Dan Campbell led the planning and execution of the measurements. Lt. James Williams, also from AFRL, Alexis Serwon (Technergetics, LLC), and Michael Senatore (Syracuse University Ph.D. student; Griffiss Institute Intern) provided assistance in setting up and/or conducting the measurements. In addition, former co-op student Santiago Delgado (Northeastern University, undergraduate; Griffiss Institute co-op, 2019) made important contributions to the design of the measurement apparatus. Finally, a team led by Prof. William Oliver and Dr. Eric Dauler from MIT Lincoln Laboratory designed, manufactured, and pre-characterized the superconducting qubits and the traveling wave parametric amplifier (TWPA) that were used in the measurements.
“A highly coherent qubit is exquisitely sensitive to environmental disturbances, so much so that a single microwave photon in the readout resonator, or a wandering normal electron on the chip, will noticeably degrade the qubit’s coherence,” said Dr. Campbell. “Proper shielding and careful microwave engineering prevents noise from the world outside the cryostat from leaking in. I’ve never seen coherence times from a transmon-type qubit chip as long as those we observed from the chip furnished by MIT-LL, verifying our newly assembled lab.”
The Air Force Research Laboratory (AFRL) is the primary scientific research and development center for the Air Force. AFRL plays an integral role in leading the discovery, development, and integration of affordable warfighting technologies for our air, space, and cyberspace force. With a workforce of more than 11,000 across nine technology areas and 40 other operations across the globe, AFRL provides a diverse portfolio of science and technology ranging from fundamental to advanced research and technology development. For more information, visit: www.afresearchlab.com.
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