Less Noise, More Gain For Quantum Computers - The Quantum Insider

PRESS RELEASE — The low-noise, high-gain properties needed for high-performance quantum computing can be realized in a microwave photonic circuit device called a Josephson traveling-wave parametric amplifier (JTWPA), RIKEN researchers have shown experimentally. This advance stands to speed up development of superconducting quantum computer systems at the 100-qubit scale. Quantum computers are extraordinary feats of research and engineering, combining highly advanced quantum physics with state-of-the-art fabrication techniques designed to physically manipulate light near the limits of quantum dynamics. While the elemental quantum bits—qubits—are where the magic of quantum computing happens, they need to be ‘read’ in order for their computations to be useful. Unfortunately, the very act of reading the state of a qubit can introduce noise and interference that obscures the data. The readout operation needs to meet several criteria: it needs to be fast enough with very high signal-to-noise ratio to be able to measure the qubit in a single shot, while operating with just a few quanta in energy (where a quantum is the energy of one microwave photon). Ideally, it should also comb multiple frequencies so it can read multiple qubits at once using the same circuit. “So far, amplifiers based on an array of Josephson junctions fulfill all of these qualities except for noise, which is what we focused on in this study,” says Sandbo Chang of the RIKEN Center for Quantum Computing (RQC). Chang, Yasunobu Nakamura, also of RQC, and co-workers have resolved a long-standing noise issue with JTWPAs. This advance promises to strengthen this highly accessible scheme for qubit signal processing. Noise is inevitably added to a readout signal when it is amplified. Quantum mechanics requires any phase-preserving amplifier with high gain to add at least half a quantum of noise. The best previous noise level achieved by a Josephson traveling-wave parametric amplifier is often one photon or more, which has limited the usefulness of this technology. “This is mostly because previous approaches use lossy dielectric material in their design,” says Chang. By dropping the use of lossy dielectric material and instead creating a spiraled fishbone-like tapered waveguide structure (Fig. 1), the team was able to reduce the noise to 0.68 quanta, only 0.18 quanta above the quantum limit. They demonstrated this through performing simulations and creating an experimental device. “Our goal was also to keep the fabrication recipe as accessible as possible,” says Nakamura. “The hope is that most labs that can already fabricate superconducting qubits will already have the techniques and equipment they need to reproduce our results.” Keep track of everything going on in the Quantum Technology Market. hbspt.forms.create({ portalId: "7697776", formId: "bb678241-852f-447e-b9b3-fdc974f72f81", region: "na1", onFormReady: function($form) { const conversionPageField = $form.find('input[name="conversion_page"]'); if (conversionPageField.length) { conversionPageField.val(window.location.href); } const verticalField = $form.find('input[name="vertical"]'); if (verticalField.length) { verticalField[0].value = 'Quantum'; } } }); [ivory-search id=”2367594″ title=”Custom Search Form”] One of our team will be in touch to learn more about your requirements, and provide pricing and access options. Necessary cookies are always on to ensure the website works. Optional cookies help us understand how the site is used.