LINAC2014 - List of Authors (Usher, N.R.)

Paper

Title

Page

Superconducting RF Development for FRIB at MSU

790

K. Saito, N.K. Bultman, E.E. Burkhardt, F. Casagrande, S.K. Chandrasekaran, S. Chouhan, C. Compton, J.L. Crisp, K. Elliott, A. Facco, A.D. Fox, P.E. Gibson, M.J. Johnson, G. Kiupel, R.E. Laxdal, M. Leitner, S.M. Lidia, I.M. Malloch, D. Miller, S.J. Miller, D. Morris, D. Norton, R. Oweiss, J.P. Ozelis, J. Popielarski, L. Popielarski, A.P. Rauch, R.J. Rose, T. Russo, S. Shanab, M. Shuptar, S. Stark, N.R. Usher, G.J. Velianoff, D.R. Victory, J. Wei, G. Wu, X. Wu, T. Xu, T. Xu, Y. Yamazaki, Q. Zhao, Z. Zheng
FRIB, East Lansing, Michigan, USA

Funding: *This material is based upon work supported by the U.S. Department of Energy Office of Science under Cooperative Agreement DE-SC0000661.
FRIB is a $730M heavy ion accelerator project and a very large scale machine for many nuclear physics users. The civil construction started on March 17th 2014. The SRF system design and development have completed. The machine is to be in early completion end of 2019. FRIB accelerates ion species up to 238U with energies of no less than 200MeV/u and provides a beam power up to 400kW. Four SRF cavity families are used from β=0.041, 0.085 (QWRs) to 0.29 and 0.53 (HWRs). 8T superconducting solenoids are installed in the cryomodules for space effective strong beam focusing. The biggest challenges are in accelerating the high-power heavy ion beams from the very low energy to medium energy and the stable operation for large user community. The SRF cryomodule design addressed three critical issues: high performance, stable operation and easy maintainability, which chose several unique technical strategies, e.g.2K operation, bottom up cryomodule assembly, local magnetic shielding and so on. This talk will include high performance cavity R&D, local magnetic shielding, flux trapping by solenoid fringe field, and bottom up cryomodule assembly.

Slides THIOA02 [5.049 MB]

THPP047

Integrated Testing of SRF Resonators with Couplers and Tuners in the Vertical Test Configuration at MSU

J. Popielarski, S.K. Chandrasekaran, M. Hodek, D. Morris, J.P. Ozelis, L. Popielarski, K. Saito, N.R. Usher, D.R. Victory, Z. Zheng
FRIB, East Lansing, Michigan, USA
A. Facco
INFN/LNL, Legnaro (PD), Italy

Funding: This material is based upon work supported by the U.S. Department of Energy Office of Science under Cooperative Agreement DE-SC0000661.
A robust and extensive program of testing using the superconducting cavity vertical test facility at MSU has been used to validate cavities and ancillary systems for FRIB. The facility has been used to validate final designs of dressed HWR & QWR cavities with integrated tuners and LLRF control systems. In each test (QWR & HWR), the FRIB coupler is working at the full rated power at the full cavity field for long term operation integrated with the FRIB LLRF controller. The final validation of the SRF subsystems are achieved with long term stable lock with FRIB specified parameters for amplitude and phase control. Topics discussed include the dynamic loads of couplers and tuners, microphonics affects & QWR mechanical mode damping, and the model used to predict RF BW requirements for stable operation based on fundamental design parameters.

Paper	Title	Page
THIOA02	Superconducting RF Development for FRIB at MSU	790
	K. Saito, N.K. Bultman, E.E. Burkhardt, F. Casagrande, S.K. Chandrasekaran, S. Chouhan, C. Compton, J.L. Crisp, K. Elliott, A. Facco, A.D. Fox, P.E. Gibson, M.J. Johnson, G. Kiupel, R.E. Laxdal, M. Leitner, S.M. Lidia, I.M. Malloch, D. Miller, S.J. Miller, D. Morris, D. Norton, R. Oweiss, J.P. Ozelis, J. Popielarski, L. Popielarski, A.P. Rauch, R.J. Rose, T. Russo, S. Shanab, M. Shuptar, S. Stark, N.R. Usher, G.J. Velianoff, D.R. Victory, J. Wei, G. Wu, X. Wu, T. Xu, T. Xu, Y. Yamazaki, Q. Zhao, Z. Zheng FRIB, East Lansing, Michigan, USA
	Funding: *This material is based upon work supported by the U.S. Department of Energy Office of Science under Cooperative Agreement DE-SC0000661. FRIB is a $730M heavy ion accelerator project and a very large scale machine for many nuclear physics users. The civil construction started on March 17th 2014. The SRF system design and development have completed. The machine is to be in early completion end of 2019. FRIB accelerates ion species up to 238U with energies of no less than 200MeV/u and provides a beam power up to 400kW. Four SRF cavity families are used from β=0.041, 0.085 (QWRs) to 0.29 and 0.53 (HWRs). 8T superconducting solenoids are installed in the cryomodules for space effective strong beam focusing. The biggest challenges are in accelerating the high-power heavy ion beams from the very low energy to medium energy and the stable operation for large user community. The SRF cryomodule design addressed three critical issues: high performance, stable operation and easy maintainability, which chose several unique technical strategies, e.g.2K operation, bottom up cryomodule assembly, local magnetic shielding and so on. This talk will include high performance cavity R&D, local magnetic shielding, flux trapping by solenoid fringe field, and bottom up cryomodule assembly.
	Slides THIOA02 [5.049 MB]

THPP047	Integrated Testing of SRF Resonators with Couplers and Tuners in the Vertical Test Configuration at MSU
	J. Popielarski, S.K. Chandrasekaran, M. Hodek, D. Morris, J.P. Ozelis, L. Popielarski, K. Saito, N.R. Usher, D.R. Victory, Z. Zheng FRIB, East Lansing, Michigan, USA A. Facco INFN/LNL, Legnaro (PD), Italy
	Funding: This material is based upon work supported by the U.S. Department of Energy Office of Science under Cooperative Agreement DE-SC0000661. A robust and extensive program of testing using the superconducting cavity vertical test facility at MSU has been used to validate cavities and ancillary systems for FRIB. The facility has been used to validate final designs of dressed HWR & QWR cavities with integrated tuners and LLRF control systems. In each test (QWR & HWR), the FRIB coupler is working at the full rated power at the full cavity field for long term operation integrated with the FRIB LLRF controller. The final validation of the SRF subsystems are achieved with long term stable lock with FRIB specified parameters for amplitude and phase control. Topics discussed include the dynamic loads of couplers and tuners, microphonics affects & QWR mechanical mode damping, and the model used to predict RF BW requirements for stable operation based on fundamental design parameters.