DOE: $9.1M Awarded for Quantum Information Science and Nuclear Physics Research

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Jan. 26, 2023 — Today, the U.S. Department of Energy (DOE) announced $9.1 million in funding for 13 projects over three years in Quantum Information Science (QIS) with relevance to nuclear physics. The list of projects and more information can be found here. The projects were selected by competitive peer review under the DOE Funding Opportunity Announcement for Quantum Horizons: QIS Research and Innovation for Nuclear Science.

Nuclear physics research seeks to discover, explore, and understand all forms of nuclear matter that can exist in the universe – from the subatomic structure of nucleons, to exploding stars, to the emergence of the quark-gluon plasma seconds after the Big Bang. Quantum computers have the potential for computational breakthroughs in classically unsolvable nuclear physics problems. Quantum sensors exploit distinct quantum phenomena that do not have classical counterparts, to acquire, process, and transmit information in ways that greatly exceed existing capabilities or sensitivities.

“Although we are just beginning to develop the knowledge and technology needed to power a revolutionary paradigm shift to quantum computing, there is a clear line of sight on how to proceed,” said Tim Hallman, DOE Associate Director of Science for Nuclear Physics. “These awards will contribute to advancing nuclear physics research and to pressing future quantum computing developments forward.”

The selected projects are at the forefront of interdisciplinary research in both fundamental research and use-inspired challenges at the interface of nuclear physics and QIS technologies. Projects include advancing the development of next generation materials and architectures for high coherence superconducting quantum bits, or “qubits,” and a solid-state quantum simulator for applications in nuclear theory. Projects will also develop quantum sensors to enhance sensitivity to new physics beyond the Standard Model and improve precision measurements of nuclear decays. The quantum computing projects explore difficult nuclear physics problems using hardware advantages offered by different near-term quantum platforms.