Dan Morris scite author profile

The Facility for Rare Isotope Beams (FRIB) Project has entered the phase of beam commissioning starting from the room-temperature front end and the superconducting linac segment of first 15 cryomodules. With the newly commissioned helium refrigeration system supplying 4.5[Formula: see text]K liquid helium to the quarter-wave resonators and solenoids, the FRIB accelerator team achieved the sectional key performance parameters as designed ahead of schedule accelerating heavy ion beams above 20[Formula: see text]MeV/u energy. Thus, FRIB accelerator becomes world’s highest-energy heavy ion linear accelerator. We also validated machine protection and personnel protection systems that will be crucial to the next phase of commissioning. FRIB is on track towards a national user facility at the power frontier with a beam power two orders of magnitude higher than operating heavy-ion facilities. This paper summarizes the status of accelerator design, technology development, construction, commissioning as well as path to operations and upgrades.

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Efficient continuous wave accelerating structure for ion beams

Ostroumov

Plastun

Bultman

et al. 2020

Phys. Rev. Accel. Beams

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The Facility for Rare Isotope Beams driver linac was designed for acceleration of multiplecharge-state beams after the stripping at ion beam energies of 17 to 20 MeV=u depending on the ion species. The linac includes a 180°achromatic bend to select multiple charge states for further acceleration and to dump unwanted charge states after the first 45°magnet. Two rf rebunchers between the stripper and the linac segment 2 (LS2) are required to minimize the effective emittance growth of the multiple-charge-state beams and provide matching to the LS2. Recent studies have shown that the best choice for these two rebunchers is a room-temperature (RT) accelerating structure capable of providing robust operation in the presence of the stripped heavy ion beam contaminants. The latter can result in uncontrolled losses of contaminant ions after the passage off the stripper. Therefore, using a superconducting (SC) rebuncher after the stripper is not rational due to possible contamination and performance degradation of SC cavities over a long period of operation. For the beam bunching in the energy range from 13 to 22 MeV=u, two 161 MHz rebunchers based on interdigital H-type (IH) structure were developed, built, installed and commissioned with beam at the FRIB linac. This is the first experimental demonstration for application of a cw RT drift tube accelerating structure in this energy range.

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FRIB Accelerator: Design and Construction Status

Wei¹,

Ao²,

Bultman³

et al. 2016

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Dan Morris

On active disturbance rejection based control design for superconducting RF cavities

Advances of the FRIB project

Efficient continuous wave accelerating structure for ion beams

FRIB Accelerator: Design and Construction Status

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