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2024年10月30日

Design study of a radio-frequency quadrupole for high-intensity beams

  • The Rare isotope Accelerator Of Newness (RAON) heavy-ion accelerator has been designed for the Rare Isotope Science Project (RISP) in Korea. The RAON will produce heavy-ion beams from 660-MeV-proton to 200-MeV/u-uranium with continuous wave (CW) power of 400 kW to support research in various scientific fields. Its system consists of an ECR ion source, LEBTs with 10 keV/u, CW RFQ accelerator with 81.25 MHz and 500 keV/u, a MEBT system, and a SC linac. In detail, the driver linac system consists of a Quarter Wave Resonator (QWR) section with 81.25 MHz and a Half Wave Resonator (HWR) section with 162.5 MHz, Linac-1, and a Spoke Cavity section with 325 MHz, Linac-2. These linacs have been designed to optimize the beam parameters to meet the required design goals. At the same time, a light-heavy ion accelerator with high-intensity beam, such as proton, deuteron, and helium beams, is required for experiments. In this paper, we present the design study of the high intensity RFQ for a deuteron beam with energies from 30 keV/u to 1.5 MeV/u and currents in the mA range. This system is composed of an Penning Ionization Gauge ion source, short LEBT with a RF deflector, and shared SC Linac. In order to increase acceleration efficiency in a short length with low cost, the 2nd harmonic of 162.5 MHz is applied as the operation frequency in the m D+ RFQ design. The m D+ RFQ is designed with 4.97 m, 1.52 bravery factor. Since it operates with 2nd harmonic frequency, the beam should be 50% of the duty factor while the cavity should be operated in CW mode, to protect the downstream linac system. We focus on avoiding emittance growth by the space-charge effect and optimizing the RFQ to achieve a high transmission and low emittance growth. Both the RFQ beam dynamics study and RFQ cavity design study for two and three dimensions will be discussed.
      PCAS:
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  • [1] RAON Accelerator and Experimental System Technical Design Report, September 30, 2013
    [2] J. Bahng et al, Proceedings of IPAC2015, MOPTY025, Richmond, USA, 2015
    [3] C. Zhang, A. Schempp, Nuclear Instruments and Methods in Physics Research A, 586: 153-159 (2008)
    [4] J. Staples, RFQ Progress, presentation at Project X collaboration Meeting at LBNL (April 10-12, 2012)
    [5] A. Pisent et al, Proceedings of EPAC08, THPP078, Genoa, Italy, 2008
    [6] Z. Zhang et al, Proceedings of LINAC2012, THPB039, Tel-Aviv, Israel, 2012
    [7] H. F. Ouyang, S. Fu, Proceedings of LINAC2006, THP070, Knoxville, Tennessee, USA, 2006
    [8] Y. Kondo, K. Hasegawa, T. Morishita, R. A. Jameson, Physical Review Special Topics-Accelerators and Beams, 15: 080101 (2012)
    [9] R. Gaur, P. Shrivastava, Journal of Electromagnetic Analysis and Applications, 2: 519-528 (2010)
    [10] A. Caliskan, H. F. Kisoglu, M. Yilmaz, Nuclear Science and Techniques, 26: 030103 (2015)
    [11] ESS Technical Design Report, April 22, 2013
    [12] RFQ Final Report, technical note SPIRAL2 EDMS-I-004532
    [13] A. Pisent et al, Proceedings of EPAC2008, THPP078, Genna, Italy, 2008
    [14] M. Marchetto et al, Proceedings of EPAC2004, TUPLT066, Lucerne, Switzerland, 2004
    [15] J. Rodnizki, Z. Horvits, Proceedings of LINAC2010, TUP045, Tsukuba, Japan, 2010
    [16] Y. R. Lu et al, Physics Procedia, 60: 212-219 (2014)
    [17] W. D. Kilpatrick, The Review of Scientific Instruments, 28(10): 1957
    [18] E. S. Kim et al, Nuclear Instruments and Methods in Physics Research A, 794: 215-223 (2015)
    [19] B. S. Park et al, Proceedings of IPAC2016, TUPMR030, Busan, Korea, 2016
    [20] K. R. Crandall, T. P. Wangler, L. M. Young, J. H. Billen, G. H. Neuschaefer, and D. L. Schrage, RFQ Design Codes, LA-UR-96-1836
    [21] N. Solyak, A. Vostrikov, Project X Front-end concept for 162.5 MHz RFQ, Project X-doc-816-v1, 2011
    [22] J. H. Billen and L. M. Yong, Poisson Superfish, LA-UR-96-1834
    [23] A. Pisent et al, Proceedings of EPAC2008, THPP078, Genoa, Italy, 2008
    [24] R. Romanov et al, Proceedings of ICAP09, THPSC047, San Francisco, CA, USA, 2009
  • 加载中

Get Citation
Jungbae Bahng, Eun-San Kim and Bong-Hyuk Choi. Design study of a radio-frequency quadrupole for high-intensity beams[J]. Chinese Physics C, 2017, 41(7): 077002. doi: 10.1088/1674-1137/41/7/077002
Jungbae Bahng, Eun-San Kim and Bong-Hyuk Choi. Design study of a radio-frequency quadrupole for high-intensity beams[J]. Chinese Physics C, 2017, 41(7): 077002.  doi: 10.1088/1674-1137/41/7/077002 shu
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Received: 2016-12-16
Revised: 2017-03-09
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    Supported by Korea University Future Research Grant

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Design study of a radio-frequency quadrupole for high-intensity beams

    Corresponding author: Eun-San Kim, eskim1@korea.ac.kr
  • 1.  Department of Physics, Kyungpook National University, Daegu 41566, Republic of Korea
  • 2.  Department of Accelerator Science, Graduate School, Korea University Sejong campus, Sejong 30019, Republic of Korea
  • 3.  Institute for Basic Science, Daejeon 34047, Republic of Korea
Fund Project:  Supported by Korea University Future Research Grant

Abstract: The Rare isotope Accelerator Of Newness (RAON) heavy-ion accelerator has been designed for the Rare Isotope Science Project (RISP) in Korea. The RAON will produce heavy-ion beams from 660-MeV-proton to 200-MeV/u-uranium with continuous wave (CW) power of 400 kW to support research in various scientific fields. Its system consists of an ECR ion source, LEBTs with 10 keV/u, CW RFQ accelerator with 81.25 MHz and 500 keV/u, a MEBT system, and a SC linac. In detail, the driver linac system consists of a Quarter Wave Resonator (QWR) section with 81.25 MHz and a Half Wave Resonator (HWR) section with 162.5 MHz, Linac-1, and a Spoke Cavity section with 325 MHz, Linac-2. These linacs have been designed to optimize the beam parameters to meet the required design goals. At the same time, a light-heavy ion accelerator with high-intensity beam, such as proton, deuteron, and helium beams, is required for experiments. In this paper, we present the design study of the high intensity RFQ for a deuteron beam with energies from 30 keV/u to 1.5 MeV/u and currents in the mA range. This system is composed of an Penning Ionization Gauge ion source, short LEBT with a RF deflector, and shared SC Linac. In order to increase acceleration efficiency in a short length with low cost, the 2nd harmonic of 162.5 MHz is applied as the operation frequency in the m D+ RFQ design. The m D+ RFQ is designed with 4.97 m, 1.52 bravery factor. Since it operates with 2nd harmonic frequency, the beam should be 50% of the duty factor while the cavity should be operated in CW mode, to protect the downstream linac system. We focus on avoiding emittance growth by the space-charge effect and optimizing the RFQ to achieve a high transmission and low emittance growth. Both the RFQ beam dynamics study and RFQ cavity design study for two and three dimensions will be discussed.

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