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

Jungbae Bahng; Eun-San Kim; Bong-Hyuk Choi

doi:10.1088/1674-1137/41/7/077002

Chinese Physics C> 2017, Vol. 41> Issue(7) : 077002 DOI: 10.1088/1674-1137/41/7/077002

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

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

Abstract
HTML
Reference
Related

PDF

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.
- heavy-ion accelerator ,
- RFQ accelerator ,
- high intensity ,
- RFQ beam dynamics ,
- RFQ cavity design

References

[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

[1]	SHI Ai-Min , SUN Lie-Peng , ZHANG Zhou-Li , XU Xian-Bo , SHI Long-Bo , LI Chen-Xing , WANG Wen-Bin . Design of the new couplers for C-ADS RFQ. Chinese Physics C, 2015, 39(4): 047004. doi: 10.1088/1674-1137/39/4/047004
[2]	DOU Wei-Ping , HE Yuan , LU Yuan-Rong . Beam dynamics design for uranium drift tube linear accelerator. Chinese Physics C, 2014, 38(7): 077001. doi: 10.1088/1674-1137/38/7/077001
[3]	LI Chao , ZHANG Zhi-Lei , QI Xin , XU Xian-Bo , HE Yuan , YANG Lei . Beam dynamics study of RFQ for CADS with a 3D space-charge-effect. Chinese Physics C, 2014, 38(3): 037005. doi: 10.1088/1674-1137/38/3/037005
[4]	WANG Zhi-Jun , HE Yuan , LIU Shu-Hui , DU Xiao-Nan , JIA Huan , LI Chao , WANG Wang-Sheng , CHEN Xi-Meng . A new compact structure for a high intensity low-energy heavy-ion accelerator. Chinese Physics C, 2013, 37(12): 127001. doi: 10.1088/1674-1137/37/12/127001
[5]	M. Y&#0 , maz . DTL cavity design and beam dynamics for a TAC linear proton accelerator. Chinese Physics C, 2012, 36(2): 167-172. doi: 10.1088/1674-1137/36/2/012
[6]	CAI Jin-Chi , XING Qing-Zi , GUAN Xia-Ling , DU Lei . Design of undercuts and dipole stabilizer rods for the CPHS RFQ accelerator. Chinese Physics C, 2012, 36(5): 464-468. doi: 10.1088/1674-1137/36/5/015
[7]	XIAO Chen , HE Yuan , LIU Yong , YUAN You-Jin , WANG Zhi-Jun , HE Shou-Bo , XU Meng-Xin , LI Chao , YUE Wei-Ming , CHANG Wei , ZHAO Hong-Wei , XIA Jia-Wen . Preliminary design and simulation of a 162.5 MHz high- intensity proton RFQ for an accelerator driven system. Chinese Physics C, 2011, 35(11): 1053-1058. doi: 10.1088/1674-1137/35/11/014
[8]	NIE Yuan-Cun , LU Yuan-Rong , CHEN Jia-Er , YAN Xue-Qing , GUO Zhi-Yu , ZHU Kun , FANG Jia-Xun . Beam dynamics and RF design of trapezoidal IH-RFQ with low energy spread. Chinese Physics C, 2009, 33(S2): 105-108. doi: 10.1088/1674-1137/33/S2/027
[9]	CHEN Jia-Er , ZHU Kun , GUO Zhi-Yu , LU Yuan-Rong , YAN Xue-Qing , GAO Shu-Li , WANG Zhi , KANG Ming-Lei , FANG Jia-Xun , YU Mao-Lin , LI Wei-Guo , GUO Ju-Fang . Power test of the separated function RFQ accelerator. Chinese Physics C, 2009, 33(S2): 56-59. doi: 10.1088/1674-1137/33/S2/015
[10]	ZHANG Meng , LU Yuan-Rong , PENG Shi-Xiang , ZHU Kun , YAN Xue-Qing , GAO Shu-Li , WANG Zhi , GUO Zhi-Yu , ZHAO Jie , FANG Jia-Xun , LI Wei-Guo , GUO Ju-Fang , YUAN Zhong-Xi , SONG Zhi-Zhong , YU Jin-Xiang , YU Mao-Lin , CHEN Jia-Er . Upgrading of a Heavy Ion 1MeV ISR RFQ Accelerator. Chinese Physics C, 2008, 32(S1): 262-264.
[11]	PENG Shi-Xiang , SONG Zhi-Zhong , QIAN Feng , YUAN Zhong-Xi , XU Rong , YU Jin-Xiang , GUO Zhi-Yu . An ECR Oxygen Source and a LEBT System Developed for 1 MeV ISR RFQ Accelerator Upgrade. Chinese Physics C, 2007, 31(S1): 63-65.
[12]	YANG Xue-Qing , FANG Jia-Xun , GUO Zhi-Yu , CHEN Jia-Rong . Matching Design Method for High Intensity RFQ Accelerators. Chinese Physics C, 2006, 30(S1): 19-21.
[13]	GUO Zhi-Yu , XIE Yi , LIU Ke-Xin , FANG Jia-Xun , YANG Xue-Qing , CHEN Jia-Rong . Physical Design of A Low-Energy-Spread RFQ Accelerator. Chinese Physics C, 2006, 30(S1): 114-116.
[14]	FU Shi-Nian , OUYANG Hua-Fu , XU Tao-Guang . Study on the Function of Dipole Stabilizer Rods in an RFQ Accelerator. Chinese Physics C, 2005, 29(3): 295-300.
[15]	ZHU Kun , GUO Zhi-Yu , FANG Jia-Xun , GUO Jiu-Fang . The Design and Simulation of a Cooling System of High Current 4-rod RFQ Cavity. Chinese Physics C, 2005, 29(8): 797-801.
[16]	HUANG Wen-Xue , WANG Yue , XU Hu-Shan , SUN Zhi-Yu , XIAO Guo-Qing , ZHAN Wen-Long . RFQ Cooler and Buncher for Radioactive Ion Beam. Chinese Physics C, 2004, 28(S1): 90-92.
[17]	GUO WeiMing , YU QingChang . Design Study of a Injector of Proton Accelerator 714MHz RFQ. Chinese Physics C, 2000, 24(3): 262-268.
[18]	Luo Zihua , Wang Shuhong . Design and Study of Beam Dynamics for the BPL-RFQ. Chinese Physics C, 1995, 19(7): 658-666.
[19]	WANG Shu-Hong . RFQ's Beam Dynamics and RF Structure. Chinese Physics C, 1993, 17(4): 310-321.
[20]	WG SHU-HIUNG . BEAM DYNAMICS DESIGN STUDY FOR RFQ LINAC. Chinese Physics C, 1982, 6(4): 428-434.

Access

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

RIS(for EndNote,Reference Manager,ProCite)

BibTex

Txt

Milestone

Received: 2016-12-16
Revised: 2017-03-09

Fund

Supported by Korea University Future Research Grant

Article Metric

Article Views(1669)
PDF Downloads(42)
Cited by(0)

Policy on re-use

To reuse of subscription content published by CPC, the users need to request permission from CPC, unless the content was published under an Open Access license which automatically permits that type of reuse.

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

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

Abstract：

References

Access

Article Metrics

Metrics

通讯作者: 陈斌, bchen63@163.com

Email This Article

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

Corresponding author: Eun-San Kim, eskim1@korea.ac.kr

HTML

目录