Researchers Discover Robust Qubit in Silicon

Insider Brief Researchers at UC Santa Barbara have identified a new hydrogen-free silicon defect known as the CN center that could serve as a robust qubit emitting telecom-wavelength light, potentially advancing scalable quantum technologies. Using first-principles computer simulations, the team found that the carbon-nitrogen defect reproduces the key electronic and optical properties of the previously studied T center while avoiding the fabrication challenges associated with hydrogen. If validated experimentally, the CN center could provide a structurally stable, manufacturable quantum light emitter in silicon, helping bridge fundamental quantum research and practical semiconductor-based device development. Image: Photo by geralt on Pixabay PRESS RELEASE — Quantum technologies are anticipated to transform computing, communication and sensing by harnessing the unusual behavior of matter at the atomic scale. Translating quantum’s promise into practical devices will require physical systems that have desirable quantum properties and can be easily manufactured. Silicon, the material behind today’s computer chips, is highly attractive as a platform because it plays to the strengths of the trillion-dollar semiconductor industry that has already been built. Identifying quantum building blocks — qubits —in silicon is, therefore, an important frontier research area. In a new study, researchers in UC Santa Barbara materials professor Chris Van de Walle’s Computational Materials Group identified a robust new qubit in silicon, called the CN center. The work is published in the journal Physical Review B. Qubits can be based on atomic-scale defects in a crystal. A prototype example is the NV center, which consists of a nitrogen (N) atom sitting next to a vacancy (V, a missing carbon atom) in a diamond crystal. These defects can interact with both electrons and light, allowing them to emit single photons (quanta of light) that can transmit quantum information or be processed in quantum networks. Recent work has focused on a silicon defect, the T center, which can store quantum information for long periods of time comparable to those of an NV center. It also emits light in the telecom band — the range of wavelengths that can be transmitted with low loss through optical fibers. The T center is made up of carbon and hydrogen atoms, and the presence of hydrogen renders it fragile and sensitive to fabrication conditions. Hydrogen can easily move within the crystal and is difficult to control during processing, making reproducible and reliable device manufacturing more challenging to achieve. In their new study, the researchers identified a promising alternative: the CN center, which consists of carbon and nitrogen atoms. “Unlike the T center, this defect does not contain hydrogen and will, therefore, be more robust and easier to realize in actual devices,” said Kevin Nangoi, a postdoctoral scholar in the Van de Walle group who led the project.

The team used advanced first-principles computer simulations to model the defect at the atomic level. Because such simulations allow researchers to predict material properties of new systems that have not yet been realized experimentally, they can guide future efforts in engineering and fabricating novel devices. “Our results show that the CN center reproduces the key electronic and optical properties that render the T center attractive for quantum applications; in particular, the center is structurally stable and produces light in the telecom range,” said Mark Turiansky, a group alumnus and now a postdoctoral researcher at the U.S.

Naval Research Laboratory, who was involved in the project. Identifying a hydrogen-free, telecom-wavelength quantum-light emitter in silicon is an important step that helps to bridge the gap between quantum science and scalable technology. Looking ahead, Van de Walle noted, “If confirmed experimentally, the CN center could serve as a practical new building block for quantum devices, potentially accelerating the development of advanced quantum technologies [while] using the same silicon material that powers today’s electronics.” Funding for this research was provided by the Department of Energy Office of Science, Office of Basic Energy Sciences, through the Co-design Center for Quantum Advantage (C2QA); the computations were performed at the National Energy Research Scientific Computing Center.

Matt Swayne LinkedIn With a several-decades long background in journalism and communications, Matt Swayne has worked as a science communicator for an R1 university for more than 12 years, specializing in translating high tech and deep tech for the general audience. He has served as a writer, editor and analyst at The Quantum Insider since its inception. In addition to his service as a science communicator, Matt also develops courses to improve the media and communications skills of scientists and has taught courses. matt@thequantuminsider.com Share this article: