Gasdynamic ECR Sources of Multichared Ions (abstract only)

S.Golubev; A.Bokhanov; I.Izotov; S.Razin; A.Sidorov; <BR>V.Skalyga; A.Vodopyanov; V.Zorin

Chinese Physics C> 2007, Vol. 31> Issue(S1) : 238-238

Gasdynamic ECR Sources of Multichared Ions (abstract only)

Institute of Applied Physics RAS, 46 Ulyanov St., Nizhny Novgorod, Russia

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A new type of pulse sources of multicharged ions, namely, a quasi-gasdynamic ECR source is propose. Its main difference from the classical ECR ion sources is a different, quasi-gasdynamic regime of plasma confinement in a magnetic trap. A zero-dimensional model was constructed that describes gas breakdown, formation of charge state distribution in a plasma, and plasma flux through the plugs of the trap. A wide spectrum of model experimental studies was covered. Plasma was produced and heated by a pulse (1ms) gyrotron at the frequency of 37.5GHz and power of 100kW in a cusp magnetic trap with magnetic field in plugs up to 2.5T. Such a trap has axisymmetric configuration and allows one to realize a quasi-gasdynamic regime of confinement with reliable stabilization of MHD perturbations. It was demonstrated that with such a confinement regime it is possible to generate multicharged ions and create intense (more than 1A/cm²) ion fluxes through the trap plugs. Comparison of results of calculations and data of experiments shows that they are in a good agreement, which allows us to predict with a high degree of certainty creation of an ECR source of a new generation.
The data obtained were used to design a pulse quasi-gasdynamic ECR ion source with pumping at the frequency of 100GHz, effective trap size 1m, average ion charge in plasma comparable with that in the best classical MCI ECR sources but with an order of magnitude higher flux density and absolute magnitude of plasma flux through trap plugs. Creation of intense plasma fluxes allows one to extract high-current MCI beams of high brightness. Transverse homogeneity of a plasma flux makes it possible to use multi-aperture extraction system for formation on broad intense MCI beams.

[1]	G.Machicoane , M.Doleans , G.Humenik , F.Marti , P.Miller , M.Steiner , J.Stetson , X.Wu , P.Zavodszky . R&D Effort at NSCL with the Off-line ECR Ion Source ARTEMIS-B. Chinese Physics C, 2007, 31(S1): 187-191.
[2]	E.Galutschek¹ , E.Salzborn² , F.Aumayr¹ , HP.Winter¹ . Compact, Low-cost, 14.5 GHz All-permanent Magnet Field ECR Ion Source. Chinese Physics C, 2007, 31(S1): 66-69.
[3]	G.S.Taki¹ , P.R.Sarma¹ , A.G.Drentje² , T.Nakagawa³ , P.K.Ray⁴ , R.K.Bhandari¹ . Observation of Burst Frequency in Extracted ECR Ion Current. Chinese Physics C, 2007, 31(S1): 170-173.
[4]	J.Ohnishi , T.Nakagawa , Y.Higurashi , M.Kidera , H.Saito , A.Goto . Design of Magnet System for RIKEN Superconducting ECR Ion Source. Chinese Physics C, 2007, 31(S1): 37-40.
[5]	P.Jardin , C.Canet , J.C.Cornell , M.Dupuis , C.Eleon , J.L.Flambard , G.Gaubert , N.Lecesne , P.Leherissier , F.Lemagnen , R.Leroy , J.Y.Pacquet , M.G.Saint laurent , A.C.C.Villari . ECR Ion Sources for Radioactive Ion Beam Production. Chinese Physics C, 2007, 31(S1): 206-210.
[6]	SHANG Yong , SUN Liang-Ting , MA Bao-Hua , ZHANG Xue-Zhen , FENG Yu-Cheng , CAO Yun , GUO Xiao-Hong , LI Xi-Xia , LI Jin-Yu , LU Wang , WANG Hui , ZHAO HUAN-Yu , LI Jie . The Lanzhou All Permanent ECR Ion Source No.1 -LAPECR1. Chinese Physics C, 2007, 31(S1): 115-117.
[7]	V.V.Bekhterev¹ , S.L.Bogomolov¹ , V.I.Datskov² , V.M.Drobin² , S.N.Dmitriev¹ , A.A.Efremov¹ , V.N.Loginov¹ , A.N.Lebedev¹ , H.Malinowski³ , V.V.Seleznev² , A.Shishov² , G.P.Tsvineva² . The Project of the Superconducting ECR Ion Source DECRIS-SC2. Chinese Physics C, 2007, 31(S1): 23-26.
[8]	P.A.Závodszky , B.Arend;D.Cole , J.DeKamp , M.Doleans , G.Machicoane , F.Marti , P.Miller , J.Moskalik , W.Nurnberger , J.Ottarson , M.Steiner , J.Stetson , J.Vincent , X.Wu , A.Zeller , Q.Zhao , . Status Report of the NSCL/MSU ECR Ion Sources. Chinese Physics C, 2007, 31(S1): 18-22.
[9]	R.Gobin , P-Y.Beauvais , A.Ben Ismail , D.Bogard , O.Delferriere , D.De Menezes , R.Duperrier , Y.Gauthier , F.Harrault , P-A.Leroy , O.Tuske , D.Uriot . ECR Light Ion Sources at CEA/Saclay. Chinese Physics C, 2007, 31(S1): 46-50.
[10]	M.Muramatsu¹ , 2 , A.Kitagawa² , Y.Iwata² , K.Yamamoto² , H.Ogawa² , S.Hojo² , Y.Sakamoto² , T.Honma² , W.Takasugi³ , M.Wakaisami³ , Y.Yoshida⁴ , T.Kubo⁵ , Y.Kato⁵ , S.Biri⁶ . Present Status of NIRS ECR Ion Sources. Chinese Physics C, 2007, 31(S1): 60-62.
[11]	C.Lyneis , D.Leitner . Concept for a Fourth Generation ECR Ion Source (abstract only). Chinese Physics C, 2007, 31(S1): 237-237.
[12]	SUN Liang-Ting , CAO Yun , FENG Yu-Cheng , LI Jin-Yu , ZHAO Hong-Wei , ZHANG Zi-Min , WANG Hui , MA Bao-Hua , HE Wei , ZHAO HUAN-Yu , GUO Xiao-Hong . Experimental Study on Ion Beam Emittance of ECR Ion Source. Chinese Physics C, 2005, 29(12): 1179-1184.
[13]	CAO Yun , MA Lei , ZHAO Hong-Wei , ZHANG Zi-Min , SUN Liang-Ting , LI Jing-Yu , FENG Yu-Cheng , LI Xi-Xia . Emittance Measurement of Highly Charged Ion Beams Extracted from ECR Ion Source Using Electric Sweep Scanner. Chinese Physics C, 2004, 28(8): 885-888.
[14]	SUN Liang-Ting , ZHAO Hong-Wei . Study on Designing of Hexapole Magnet of ECR Ion Source. Chinese Physics C, 2004, 28(6): 644-649.
[15]	ZHANG Zi-Min , ZHAO Hong-Wei , ZHANG Xue-Zhen , GUO Xiao-Hong , LI Xi-Xia , LI Jin-Yu , FENG Yu-Cheng , WANG Hui , MA Bao-Hua , GAO Ji-Yuan , CAO Yun , SUN Liang-Ting , MA Lei . High Charge State ECR Ion Source-LECR3. Chinese Physics C, 2003, 27(10): 914-918.
[16]	SONG Pei , GUO Xiao-Hong , ZHAO Hong-Wei , ZHANG Zi-Min , FENG Yu-Cheng , LI Jing-Yu , ZHANG Xue-Zhen . Production of Pulsed Ion Beams by ECR Ion Source Afterglow Mode. Chinese Physics C, 2001, 25(10): 1029-1034.
[17]	ZHANG ZiMin , ZHAO HongWei , ZHAO YuBin , ZHANG XueZhen , GUO XiaoHong , LIU ZhanWen . Production of Metallic Ions Beam in ECR Ion Source. Chinese Physics C, 2000, 24(10): 974-978.
[18]	Zhao Hongwei , Liu Zhanwen , Zhang Xuezhen , Guo Xiaohong , Gao Jiyuan , Zhang Zimin , Yuan Ping , Zhang Wen , Lei Hailiang , Cao Yun , Feng Yucheng , Li Jinyu , Wang Hui , Ma Baohua , Wang Yifang , Wei Baowen . A 14.5GHz New ECR Ion Source With High Charge State and High Magnetic Field. Chinese Physics C, 1999, 23(7): 717-722.
[19]	Zhao Yubin , Liu Zhanwei , Zhao Hongwei , Ding Junzhang , Cao Yun , Zhang Zimin , Zhang Xuezhen , Guo Xiaohong . A Single Charge State ECR Ion Source. Chinese Physics C, 1999, 23(11): 1125-1128.
[20]	XU Yong-Xing , LIU Zhan-Wen , WEI Bao-Wen . Design Calculation of a Improved ECR Ion Source. Chinese Physics C, 1991, 15(4): 343-348.

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S.Golubev, A.Bokhanov, I.Izotov, S.Razin, A.Sidorov,
V.Skalyga, A.Vodopyanov and V.Zorin. Gasdynamic ECR Sources of Multichared Ions (abstract only)[J]. Chinese Physics C, 2007, 31(S1): 238-238.

S.Golubev, A.Bokhanov, I.Izotov, S.Razin, A.Sidorov,
V.Skalyga, A.Vodopyanov and V.Zorin. Gasdynamic ECR Sources of Multichared Ions (abstract only)[J]. Chinese Physics C, 2007, 31(S1): 238-238. shu

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Received: 2007-05-30
Revised: 1900-01-01

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通讯作者: 陈斌, bchen63@163.com

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沈阳化工大学材料科学与工程学院沈阳 110142

Gasdynamic ECR Sources of Multichared Ions (abstract only)

Corresponding author: S.Golubev,

Institute of Applied Physics RAS, 46 Ulyanov St., Nizhny Novgorod, Russia

Received Date: 2007-05-30

Accepted Date: 1900-01-01

Available Online: 2007-01-03

Abstract: A new type of pulse sources of multicharged ions, namely, a quasi-gasdynamic ECR source is propose. Its main difference from the classical ECR ion sources is a different, quasi-gasdynamic regime of plasma confinement in a magnetic trap. A zero-dimensional model was constructed that describes gas breakdown, formation of charge state distribution in a plasma, and plasma flux through the plugs of the trap. A wide spectrum of model experimental studies was covered. Plasma was produced and heated by a pulse (1ms) gyrotron at the frequency of 37.5GHz and power of 100kW in a cusp magnetic trap with magnetic field in plugs up to 2.5T. Such a trap has axisymmetric configuration and allows one to realize a quasi-gasdynamic regime of confinement with reliable stabilization of MHD perturbations. It was demonstrated that with such a confinement regime it is possible to generate multicharged ions and create intense (more than 1A/cm²) ion fluxes through the trap plugs. Comparison of results of calculations and data of experiments shows that they are in a good agreement, which allows us to predict with a high degree of certainty creation of an ECR source of a new generation.
The data obtained were used to design a pulse quasi-gasdynamic ECR ion source with pumping at the frequency of 100GHz, effective trap size 1m, average ion charge in plasma comparable with that in the best classical MCI ECR sources but with an order of magnitude higher flux density and absolute magnitude of plasma flux through trap plugs. Creation of intense plasma fluxes allows one to extract high-current MCI beams of high brightness. Transverse homogeneity of a plasma flux makes it possible to use multi-aperture extraction system for formation on broad intense MCI beams.

Gasdynamic ECR Sources of Multichared Ions (abstract only)

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Gasdynamic ECR Sources of Multichared Ions (abstract only)

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