This page describes the Technical Division contribution to LARP. More information can be found at the LARP website:

  • Assembling a Fermilab-built Hi-Lumi coil in a magnetic mirror configuration for testing. The mirror structure was developed by the Technical Division to enable quick feedback for design and fabrication.
The US LHC Accelerator Research Program or LARP was initiated in 2003 to develop and protect US investment in accelerator technology through the commissioning, operation, and upgrade of the LHC. For more than a decade the program has developed high-performance Nb3Sn quadrupoles for interaction region beam focusing. In addition, LARP continues to develop crab cavities for bunch rotating and luminosity leveling as well as wide-band feed back systems for beam instabilities. LARP R&D is predominately focused on the pending Hi-Lumi LHC upgrade where the integrated luminosity is to increase by a factor of 10. Currently LARP leadership is housed in the Technical Division.

The LARP collaboration is comprised of four primary member laboratories:

  • Fermi National Accelerator Laboratory
  • Brookhaven National Laboratory
  • Lawrence Berkeley National Laboratory
  • Stanford Linear Accelerator Center

Old Dominion University and Jefferson Laboratory also contribute to LARP crab cavity efforts

Interaction Region Quadrupoles

A key technology for Hi-Lumi LHC are large aperture Nb3Sn interaction region quadrupoles for final beam focusing. LARP has incrementally and successfully developed 90, 120, and 150 mm aperture quadrupoles using the brittle yet powerful material Nb3Sn. This development has taken place over the past 10 years with sufficient robustness to enable deployment in the LHC.

The Technical Division is heavily involved in the fabrication of the Hi-Lumi LHC Interaction quadrupoles from winding to testing. All prototype coils for the Hi-Lumi upgrade are wound and cured with a ceramic binder for handling in the Industrial Building Complex. The superconductor technology requires a 640°C Nb3Sn formation heat treatment and subsequent epoxy impregnation accomplished by the Technical Division. After four coils are assembled and preloaded into a magnetic flux return, the full magnet structure is cold tested within the Technical Division’s test facility.

Crab Cavities

Beams of particles cross at slight angles when they collide which reduce the collision rate for typical particle colliders. To increase the number of collisions and thus the luminosity each beam bunch can be slightly rotated increasing the cross sectional area. In Hi-Lumi LHC this rotation will be achieved by superconducting RF Crab cavities. Crab cavities are under development in the Technical Division for ‘kicking’ the nose and tail of each bunch in opposite directions to maxim the luminosity increase for Hi-Lumi LHC.

Contact: Giorgio Apollinari