SRF2011 - List of Authors (Hodek, M.)

Paper

Title

Page

Design Status of the SRF Linac Systems for the Facility for Rare Isotope Beams

56

M. Leitner, J. Bierwagen, J. Binkowski, S. Bricker, C. Compton, J.L. Crisp, L.J. Dubbs, K. Elliott, A. Facco, A. Fila, R. Fontus, A.D. Fox, P.E. Gibson, P. Guetschow, L.L. Harle, M. Hodek, J.P. Holzbauer, M.J. Johnson, S. Jones, T. Kole, B.R. Lang, D. Leitner, I.M. Malloch, F. Marti, D. R. Miller, S.J. Miller, T. Nellis, D. Norton, R. Oweiss, J. Popielarski, L. Popielarski, X. Rao, G.J. Velianoff, N. Verhanovitz, J. Wei, J. Weisend, M. Williams, K. Witgen, J. Wlodarczak, Y. Xu, Y. Zhang
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
The Facility for Rare Isotope Beams (FRIB) will utilize a powerful, superconducting heavy-ion driver linac to provide stable ion beams from protons to uranium, at energies of > 200 MeV/u at a beam power of up to 400 kW. ECR ion sources installed above ground will be used to provide highly charged ions, that will be transported into the linac tunnel approx. 10 m below ground. For the heaviest ions, two charge states will be accelerated to about 0.5 MeV/u using a room-temperature 80.5 MHz RFQ and injected into a superconducting cw linac, consisting of 112 quarter-wave (80.5 MHz) and 229 half-wavelength (322 MHz) cavities, installed inside 52 cryomodules operating at 2K. A single stripper section will be located at about 17 MeV/u (for uranium). Transverse focusing along the linac will be achieved by 9 T superconducting solenoids within the same cryostat as the superconducting rf accelerating structures. This paper describes the matured linac design, as the project is progressing towards a Department of Energy performance baseline definition in 2012. Development status of the linac subcomponents are presented with emphasis on the superconducting RF components.

Poster MOPO009 [2.495 MB]

MOPO055

Superconducting Resonator Production for Ion Linac at Michigan State University

226

C. Compton, A. Facco, W. Hartung, M. Hodek, J.P. Holzbauer, M.J. Johnson, T. Kole, M. Leitner, F. Marti, D. R. Miller, S.J. Miller, J. Popielarski, L. Popielarski, J. Wei, K. Witgen, J. Wlodarczak
FRIB, East Lansing, Michigan, USA

Funding: Work supported by US DOE Cooperative Agreement DE-SC0000661 and Michigan State University
Superconducting quarter-wave resonators and half-wave resonators are being prototyped and fabricated at Michigan State University (MSU) in effort to support the Facility for Rare Isotope Beams (FRIB) project. FRIB requires a 200 MeV per nucleon driver linac, operating 345 resonators at two frequencies (80.5 and 322 MHz) and four betas (0.041, 0.085, 0.29, and 0.53). FRIB cavity development work is underway, with the prototyping of all four resonators, including helium vessel design, stiffening strategy, and tuner interface. In addition, the acquisition strategy for FRIB resonators is being finalized, and the technology transfer program is being initiated. The status of the resonator production effort will be presented in this paper, including an overview of the acquisition strategy for FRIB.

TUPO004

Development and Testing of Prototype Fundamental Power Couplers for FRIB Half Wave Resonators

353

J. Popielarski, P. Glennon, M. Hodek, J. Wlodarczak
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.
The driver linac for the Facility for Rare Isotope Beams (FRIB) requires superconducting Half Wave Resonators to accelerate ions to 200 MeV per nucleon. The Fundamental Power Coupler (FPC) is designed to deliver up to 14 kW of RF power at 322 MHz to the resonator and the beam in CW, and to increase the resonator’s control bandwidth for stable operation. With the resonator over-coupled, the mismatch creates a standing wave in the FPC and transmission line downstream of the circulator. The FPC includes an alumina vacuum barrier to allow the resonator to be under ultra-high vacuum. The FPC also serves as a thermal break between the room-temperature transmission line and the resonator at 2 K, with thermal intercepts designed to minimize the heat load to the cryoplant. The FPC design allows for some variation in the coupling, in case a larger bandwidth is needed to mitigate microphonic disturbances. The RF and mechanical design of the coupler and conditioning stand will be reviewed, and the results of high power RF conditioning and testing will be presented.

THIOB03

Status of the ReAccelerator Facility RεA for Rare Isotopes

674

D. Leitner, D. Morris, S. Nash, G. Perdikakis, N.R. Usher
NSCL, East Lansing, Michigan, USA
C. Compton, A. Facco, M. Hodek, J. Popielarski, W. Wittmer, X. Wu, Q. Zhao
FRIB, East Lansing, Michigan, USA

The Facility for Rare Isotope Beams (FRIB) at Michigan State University (MSU) is currently in the preliminary design phase. FRIB consists of a heavy ion driver LINAC, followed by a fragmentation target station, and a ReAccelerator facility (RεA). In its final configuration, RεA will provide heavy ion beams from 0.3 MeV/u to 12 MeV/u for heaviest ions and up to 20 MeV/u for light ions. While FRIB plans to start conventional construction in 2012, the first stage of RεA is already under commissioning and will be connected to the Coupled Cyclotron Facility at MSU end of 2012. The front end of the accelerator consists of a gas stopper, an Electron Beam Ion Trap (EBIT) charge state booster, a room temperature RFQ, followed by a short SRF LINAC, which contains seven β=0.041, eight β=0.085 QWR cavities, and eight 9T focusing solenoids. RεA serves as prototyping test bed for the FRIB cryomodule development since FRIB utilizes similar cavities as installed on RεA. An overview and status of the RεA facility will be presented. The presentation will focus on the testing, beam commissioning, and operational experience of the first β=0.041 cryomodules.

Paper	Title	Page
MOPO009	Design Status of the SRF Linac Systems for the Facility for Rare Isotope Beams	56
	M. Leitner, J. Bierwagen, J. Binkowski, S. Bricker, C. Compton, J.L. Crisp, L.J. Dubbs, K. Elliott, A. Facco, A. Fila, R. Fontus, A.D. Fox, P.E. Gibson, P. Guetschow, L.L. Harle, M. Hodek, J.P. Holzbauer, M.J. Johnson, S. Jones, T. Kole, B.R. Lang, D. Leitner, I.M. Malloch, F. Marti, D. R. Miller, S.J. Miller, T. Nellis, D. Norton, R. Oweiss, J. Popielarski, L. Popielarski, X. Rao, G.J. Velianoff, N. Verhanovitz, J. Wei, J. Weisend, M. Williams, K. Witgen, J. Wlodarczak, Y. Xu, Y. Zhang 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 The Facility for Rare Isotope Beams (FRIB) will utilize a powerful, superconducting heavy-ion driver linac to provide stable ion beams from protons to uranium, at energies of > 200 MeV/u at a beam power of up to 400 kW. ECR ion sources installed above ground will be used to provide highly charged ions, that will be transported into the linac tunnel approx. 10 m below ground. For the heaviest ions, two charge states will be accelerated to about 0.5 MeV/u using a room-temperature 80.5 MHz RFQ and injected into a superconducting cw linac, consisting of 112 quarter-wave (80.5 MHz) and 229 half-wavelength (322 MHz) cavities, installed inside 52 cryomodules operating at 2K. A single stripper section will be located at about 17 MeV/u (for uranium). Transverse focusing along the linac will be achieved by 9 T superconducting solenoids within the same cryostat as the superconducting rf accelerating structures. This paper describes the matured linac design, as the project is progressing towards a Department of Energy performance baseline definition in 2012. Development status of the linac subcomponents are presented with emphasis on the superconducting RF components.
	Poster MOPO009 [2.495 MB]

MOPO055	Superconducting Resonator Production for Ion Linac at Michigan State University	226
	C. Compton, A. Facco, W. Hartung, M. Hodek, J.P. Holzbauer, M.J. Johnson, T. Kole, M. Leitner, F. Marti, D. R. Miller, S.J. Miller, J. Popielarski, L. Popielarski, J. Wei, K. Witgen, J. Wlodarczak FRIB, East Lansing, Michigan, USA
	Funding: Work supported by US DOE Cooperative Agreement DE-SC0000661 and Michigan State University Superconducting quarter-wave resonators and half-wave resonators are being prototyped and fabricated at Michigan State University (MSU) in effort to support the Facility for Rare Isotope Beams (FRIB) project. FRIB requires a 200 MeV per nucleon driver linac, operating 345 resonators at two frequencies (80.5 and 322 MHz) and four betas (0.041, 0.085, 0.29, and 0.53). FRIB cavity development work is underway, with the prototyping of all four resonators, including helium vessel design, stiffening strategy, and tuner interface. In addition, the acquisition strategy for FRIB resonators is being finalized, and the technology transfer program is being initiated. The status of the resonator production effort will be presented in this paper, including an overview of the acquisition strategy for FRIB.

TUPO004	Development and Testing of Prototype Fundamental Power Couplers for FRIB Half Wave Resonators	353
	J. Popielarski, P. Glennon, M. Hodek, J. Wlodarczak 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. The driver linac for the Facility for Rare Isotope Beams (FRIB) requires superconducting Half Wave Resonators to accelerate ions to 200 MeV per nucleon. The Fundamental Power Coupler (FPC) is designed to deliver up to 14 kW of RF power at 322 MHz to the resonator and the beam in CW, and to increase the resonator’s control bandwidth for stable operation. With the resonator over-coupled, the mismatch creates a standing wave in the FPC and transmission line downstream of the circulator. The FPC includes an alumina vacuum barrier to allow the resonator to be under ultra-high vacuum. The FPC also serves as a thermal break between the room-temperature transmission line and the resonator at 2 K, with thermal intercepts designed to minimize the heat load to the cryoplant. The FPC design allows for some variation in the coupling, in case a larger bandwidth is needed to mitigate microphonic disturbances. The RF and mechanical design of the coupler and conditioning stand will be reviewed, and the results of high power RF conditioning and testing will be presented.

THIOB03	Status of the ReAccelerator Facility RεA for Rare Isotopes	674
	D. Leitner, D. Morris, S. Nash, G. Perdikakis, N.R. Usher NSCL, East Lansing, Michigan, USA C. Compton, A. Facco, M. Hodek, J. Popielarski, W. Wittmer, X. Wu, Q. Zhao FRIB, East Lansing, Michigan, USA
	The Facility for Rare Isotope Beams (FRIB) at Michigan State University (MSU) is currently in the preliminary design phase. FRIB consists of a heavy ion driver LINAC, followed by a fragmentation target station, and a ReAccelerator facility (RεA). In its final configuration, RεA will provide heavy ion beams from 0.3 MeV/u to 12 MeV/u for heaviest ions and up to 20 MeV/u for light ions. While FRIB plans to start conventional construction in 2012, the first stage of RεA is already under commissioning and will be connected to the Coupled Cyclotron Facility at MSU end of 2012. The front end of the accelerator consists of a gas stopper, an Electron Beam Ion Trap (EBIT) charge state booster, a room temperature RFQ, followed by a short SRF LINAC, which contains seven β=0.041, eight β=0.085 QWR cavities, and eight 9T focusing solenoids. RεA serves as prototyping test bed for the FRIB cryomodule development since FRIB utilizes similar cavities as installed on RεA. An overview and status of the RεA facility will be presented. The presentation will focus on the testing, beam commissioning, and operational experience of the first β=0.041 cryomodules.