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In the early morning of Dec. 24, 2019 – days ahead of a critical deadline, and just hours before Cornell closed its facilities for winter break – the physicists developing an energy-conserving particle accelerator that was first envisioned more than 50 years ago achieved something they'd hardly dared to imagine: success.

"We could not believe it," said Georg Hoffstaetter, professor of physics and a principal investigator for the Cornell-BNL ELR Test Accelerator Facility, known as CBETA. "The team had been in the control room for weeks until often 2 or 3 a.m., and then things finally came together on the last day before vacation – it was just a miracle. None of us could sleep."

CBETA, constructed in collaboration with the U.S. Department of Energy's Brookhaven National Laboratory at Cornell's Wilson Synchrotron Lab, is the first of a new breed of accelerator, which can provide particle beams with unprecedented properties and power by capturing and reusing the energy of the accelerated beams. Its construction was funded primarily by the New York State Energy Research and Development Authority.

The accelerator saves additional energy by steering the beams with permanent magnets, instead of electromagnets, and by accelerating the beams with superconducting radio frequency units.

The successful technology is poised to transform the field, with new capabilities that can power the world's largest accelerators to help scientists unlock the mysteries of the universe. Large particle accelerators can consume up to half a gigawatt of power – about half the capacity of a nuclear power plant. This makes it impossible for the machines to perform certain functions, both because of the cost and the risk of melting components.

CBETA – a collaboration between scientists from Cornell, Brookhaven National Laboratory on Long Island and nine other institutions – reduces that energy requirement by large factors.

"This is really important because several projects in the world are based on the hope that this could be done," Hoffstaetter said. "Showing that it works opens up a whole new space for future projects."

These unprecedented particle beams have potential applications in areas including elementary particle physics, nuclear physics, computer chip printing and X-ray science.

CBETA's success will also impact the development of the proposed Electron-Ion Collider, the next large accelerator planned for nuclear physics in the US. That machine would collide electrons with protons and nuclei in order to shed light on the little-understood inner workings of atomic nuclei and the building blocks of matter. The National Academy of Sciences identified the Electron-Ion Collider as the nation's highest-priority large accelerator for nuclear physics.

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