Cryocooler Cools an Accelerator Cavity

October 17, 2018

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A superconducting radio-frequency (RF) accelerator cavity is mounted and connected to a cryocooler, cooling the cavity without the use of liquid helium. This new device could make it easier to produce high-average-power electron beams for industrial applications.

The Science

Particle accelerators are made of structures called cavities, which impart energy to the particle beam, kicking it forward. One type of cavity is the superconducting radio-frequency, or SRF, cavity. Usually made of niobium, SRF cavities require extreme cold to operate. A Fermilab team developed a new way of cooling SRF cavities without liquid helium. The new system is simple to construct and easier to operate.

The Impact

Electron beams could help clean water and repair roads, and SRF is an energy-efficient technology able to produce powerful enough electron beams. The barrier is liquid helium that cools the accelerating cavity. For the first time, a team has cooled a superconducting accelerator cavity without liquid helium. Replacing liquid helium with plug-and-play devices called cryocoolers could make SRF technology available to industry. Energy-efficient SRF accelerators can provide high-average-power electron beams. The beams could strengthen materials, reconstruct asphalt pavement, treat wastewater, and more.

Summary

All SRF particle accelerators to-date use liquid helium to maintain the extremely cold temperatures necessary for sustaining superconductivity. Liquid-helium operation demands complex infrastructure: a liquefaction plant, distribution lines, gas recovery, purification systems, and cavity cryomodules that can withstand high pressure. There are also safety hazards associated with operation of the liquid helium. Although such an infrastructure is appropriate for large-scale research accelerators, it can be too complex and costly for industrial applications.

For the first time, a team at Fermilab's Illinois Accelerator Research Center has cooled an accelerating cavity to cryogenic temperatures without the use of liquid helium. They achieved this by connecting a cavity to a commercially available cryocooler, using a Fermilab-patented technology.

Connecting the cavity to the cryocooler was a significant challenge that required investigating various materials and designing custom components. The team produced niobium conduction rings and connected them to the cavity shell using electron-beam welding. They also developed niobium-aluminum joints that allowed heat to flow easily from the cavity to the cryocooler. To generate heat into the cavity, the team used a simple plug-and-play radio-frequency driver, as in laboratory accelerators.

Electromagnetic gradients are generated within SRF cavities; stronger gradients impart more energy to the beam. This first-ever cryogen?free operation produced a gradient of 0.5 MV/m on a single-cell, 650-MHz niobium cavity. Fermilab researchers plan to soon achieve gradients up to 10 MV/m by using higher capacity cryocoolers and capitalizing on other recent advances in cavity technology. The team is exploring the application of conduction cooling technology to higher frequencies, multicell cavities, and other radio-frequency structures.

Contact

Charles Thangaraj
Fermilab Illinois Accelerator Research Center
jtobin@fnal.gov

Ram Dhuley
Fermilab Illinois Accelerator Research Center
rdhuley@fnal.gov

Michael Geelhoed
Fermilab Illinois Accelerator Research Center
geelhoed@fnal.gov

Oleg Prokofiev
Fermilab Applied Physics and Superconducting Technology Division
prokofoe@fnal.gov

Funding

The Department of Energy, Office of Science, Office of High Energy Physics funded this research.

Publications

R.C. Dhuley, M.I. Geelhoed, and J.C.T. Thangaraj, "Thermal resistance of pressed contacts of aluminum and niobium at liquid helium temperatures" Cryogenics 93, 86 (2018). [DOI: 10.1016/j.cryogenics.2018.06.003]

R. Kephart, "Conduction cooling systems for linear accelerator cavities." U.S. Patent 9642239 B2, May 2, 2017.

Highlight Categories

Program: HEP

Performer/Facility: DOE Laboratory