ECRIS2012 - Classification: Superconducting ECRIS

Paper

Title

Page

Coupling Microwave Power into ECR Ion Source Plasmas at Frequencies above 20 GHz

1

C.M. Lyneis, J.Y. Benitez, M.M. Strohmeier, D.S. Todd
LBNL, Berkeley, California, USA

Electron Cyclotron Resonance (ECR) ion sources have been built to operate at frequencies from 5 GHz to 28 GHz and typically use a plasma chamber that serves as a multi-mode cavity. For small sources operating at 6 to 14 GHz cavity mode-like behavior has been reported. In these cavities the vacuum mode density is low enough that it may be that the RF power distribution can be understood in terms of excitation of a few modes. The large superconducting ECR ion sources, such as VENUS, operating at higher frequencies have a much greater mode density and very strong damping from plasma microwave adsorption. In this type of source, how the RF is launched into the plasma chamber will strongly affect the microwave coupling and the chamber walls will be less important. The VENUS source uses round over-moded TE01 mode waveguide to couple to the plasma, while most modern fusion devices use quasi-gaussian HE11 waves for injection into plasmas. In this paper we will describe the potential advantages of applying this technology to superconducting ECR ion sources as well as designs for doing so with VENUS.

Slides TUXO01 [18.302 MB]

TUPP17

Installation and Operation of a 28 GHz Gyrotron for the RIKEN Superconducting ECR Ion Source

71

J. Ohnishi, Y. Higurashi, T. Nakagawa
RIKEN Nishina Center, Wako, Japan

The RIKEN 28-GHz ECRIS uses a gyrotron microwave source fabricated by Mitsubishi Electric Corporation. The maximum output power is 10 kW. The gyrotron produces TE02-mode microwaves, which are converted into the TE01 mode by a mode converter. In the first test on the gyrotron performed using a dummy load, we observed the 50-300 Hz ripples of ~500 W in the output power of 1-7 kW, and it was difficult to make a stable operation in the low-power. These ripples were reduced to one-tenth by stabilizing the cathode voltage and then the gyrotron could produce microwaves from < 0.5 kW stably. The operation of the ion source with the 28 GHz gyrotron was started in 2011 and the ion source supplied U and Xe beams to the RIBF for two months. The power of the microwaves fluctuated slowly in the range of 870-1250 W, which influenced the beam current from the ion source. This fluctuation was caused by a slight change of the current of the solenoid of the gyrotron depending on the room temperature. We replaced the power supply with new one which has a current stability of 10ppm per day, and stabilized the microwave power in the range of 5% in the operation of 2 kW successfully.

THXO02

Current Developments of the VENUS Ion Source in Research and Operations

153

J.Y. Benitez, K.Y. Franzen, C.M. Lyneis, L. Phair, M.M. Strohmeier
LBNL, Berkeley, California, USA
G. Machicoane
FRIB, East Lansing, Michigan, USA
L.T. Sun
IMP, Lanzhou, People's Republic of China

The VENUS ion source functions as a research and development tool in the ECR community as well as an injector for LBNL's 88-Inch cyclotron. In order to meet the needs of both the ECR community and users at the 88-Inch cyclotron, technology such as ovens and a sputter probe have been developed for introducing metals into the plasma. Using a modified high temperature oven, VENUS has produced 450 eμA of ²³⁸U³³⁺ and 400 eμA of ²³⁸U³⁴⁺, twice the required Uranium beam current needed for FRIB. In addition, after upgrading its high voltage capabilities VENUS produced 11emA of ⁴He²⁺, a capability that remains unparalleled by other ECR ion sources. In addition to its recent record high intensities VENUS is also being developed to deliver low intensity, ultra high charge state ions for the cocktails beams, where many species are produced simultaneously for use by the BASE Facility. ¹²⁴Xe⁴³⁺ is now in regular production for the 16 MeV/u cocktail, and development of ²⁰⁹Bi⁵⁶⁺ for the 10 MeV/u cocktail is in progress and has been accelerated through the 88-Inch cyclotron. This paper presents the latest work towards integrating the VENUS ion source into our research and operational goals.

Slides THXO02 [8.391 MB]

THXO03

Recent RIKEN 28 GHz SC-ECRIS Results

159

Y. Higurashi, M. Fujimaki, H. Haba, O. Kamigaito, M. Kidera, M. Komiyama, J. Ohnishi, K. Ozeki
RIKEN Nishina Center, Wako, Japan
T. Aihara, M. Tamura, A. Uchiyama
SHI Accelerator Service Ltd., Tokyo, Japan

For increasing the beam intensity of highly charged heavy ions at RIKEN RIBF, we constructed new SC-ECR ion source. In the spring of 2011, we injected 28GHz microwave into the ion source and obtained first beam. Since then, we made several test experiments for increasing the beam intensity of highly charged Xe and U ion beam, and produced ~60 eμA of U³⁵⁺, ~90 eμA of U³³⁺ at the injected RF power of ~2 kW using sputtering method. In case of Xe²⁵⁺, 250 euA was obtained at RF power of 1.7 kW. Using sputtering method, we produced U³⁵⁺ ion beam longer than one month for the RIBF experiment without break. In the beginning of 2012, we installed additional GM-JT refrigerator to increase the cooling power at 4.2 K, then the total cooling power became higher than 9 W. Using it, we can use higher than 8 W of cooling power for heat load due to the absorbed X-rays. In this summer, we will install the new plasma chamber made of Al for increasing the cooling power. We will also use high temperature oven to increase the U vapor. In this contribution, we report the recent modification of the ion source and test experiments for production of U and Xe ion beam.

Slides THXO03 [49.487 MB]

THXO04

SECRAL status and future challenge

H.W. Zhao, W. Lu, L.T. Sun, D. Xie, X.Z. Zhang
IMP, Lanzhou, People's Republic of China

SECRAL, the superconducting ECR ion source at IMP, has been in routine operation for the HIRFL accelerator complex since May 2007. The total operation beam time provided by SECRAL has so far exceeded 9500 hours. In most cases SECRAL has been operating at 18 GHz for the accelerator complex, and only operating at 24 GHz for the very high charge states and very heavy ion beams such as Bi and U beams. Uranium beam was tested at 24 GHz with ion sputtering in which 160 eμA of ²³⁸U³³⁺ was produced, and ²³⁸U³²⁺ beam was delivered to the accelerator continuously for almost one month. Beam long-term stability and emittance at high rf power of 24 GHz were studied. The operation status and the latest performance of SECRAL ion source will be presented. A new heavy ion accelerator facility HIAF has been proposed at IMP. HIAF requests an ion source capable of producing a pulse beam of 2.0 emA of ²³⁸U³⁴⁺. A next generation superconducting ECR ion source with operating frequency up to 50-60 GHz is under consideration in which a few options for the superconducting magnet configuration are being studied. Technical challenges for the next generation ECR ion source will be reviewed.

Slides THXO04 [12.086 MB]

Paper	Title	Page
TUXO01	Coupling Microwave Power into ECR Ion Source Plasmas at Frequencies above 20 GHz	1
	C.M. Lyneis, J.Y. Benitez, M.M. Strohmeier, D.S. Todd LBNL, Berkeley, California, USA
	Electron Cyclotron Resonance (ECR) ion sources have been built to operate at frequencies from 5 GHz to 28 GHz and typically use a plasma chamber that serves as a multi-mode cavity. For small sources operating at 6 to 14 GHz cavity mode-like behavior has been reported. In these cavities the vacuum mode density is low enough that it may be that the RF power distribution can be understood in terms of excitation of a few modes. The large superconducting ECR ion sources, such as VENUS, operating at higher frequencies have a much greater mode density and very strong damping from plasma microwave adsorption. In this type of source, how the RF is launched into the plasma chamber will strongly affect the microwave coupling and the chamber walls will be less important. The VENUS source uses round over-moded TE01 mode waveguide to couple to the plasma, while most modern fusion devices use quasi-gaussian HE11 waves for injection into plasmas. In this paper we will describe the potential advantages of applying this technology to superconducting ECR ion sources as well as designs for doing so with VENUS.
	Slides TUXO01 [18.302 MB]

TUPP17	Installation and Operation of a 28 GHz Gyrotron for the RIKEN Superconducting ECR Ion Source	71
	J. Ohnishi, Y. Higurashi, T. Nakagawa RIKEN Nishina Center, Wako, Japan
	The RIKEN 28-GHz ECRIS uses a gyrotron microwave source fabricated by Mitsubishi Electric Corporation. The maximum output power is 10 kW. The gyrotron produces TE02-mode microwaves, which are converted into the TE01 mode by a mode converter. In the first test on the gyrotron performed using a dummy load, we observed the 50-300 Hz ripples of ~500 W in the output power of 1-7 kW, and it was difficult to make a stable operation in the low-power. These ripples were reduced to one-tenth by stabilizing the cathode voltage and then the gyrotron could produce microwaves from < 0.5 kW stably. The operation of the ion source with the 28 GHz gyrotron was started in 2011 and the ion source supplied U and Xe beams to the RIBF for two months. The power of the microwaves fluctuated slowly in the range of 870-1250 W, which influenced the beam current from the ion source. This fluctuation was caused by a slight change of the current of the solenoid of the gyrotron depending on the room temperature. We replaced the power supply with new one which has a current stability of 10ppm per day, and stabilized the microwave power in the range of 5% in the operation of 2 kW successfully.

THXO02	Current Developments of the VENUS Ion Source in Research and Operations	153
	J.Y. Benitez, K.Y. Franzen, C.M. Lyneis, L. Phair, M.M. Strohmeier LBNL, Berkeley, California, USA G. Machicoane FRIB, East Lansing, Michigan, USA L.T. Sun IMP, Lanzhou, People's Republic of China
	The VENUS ion source functions as a research and development tool in the ECR community as well as an injector for LBNL's 88-Inch cyclotron. In order to meet the needs of both the ECR community and users at the 88-Inch cyclotron, technology such as ovens and a sputter probe have been developed for introducing metals into the plasma. Using a modified high temperature oven, VENUS has produced 450 eμA of ²³⁸U³³⁺ and 400 eμA of ²³⁸U³⁴⁺, twice the required Uranium beam current needed for FRIB. In addition, after upgrading its high voltage capabilities VENUS produced 11emA of ⁴He²⁺, a capability that remains unparalleled by other ECR ion sources. In addition to its recent record high intensities VENUS is also being developed to deliver low intensity, ultra high charge state ions for the cocktails beams, where many species are produced simultaneously for use by the BASE Facility. ¹²⁴Xe⁴³⁺ is now in regular production for the 16 MeV/u cocktail, and development of ²⁰⁹Bi⁵⁶⁺ for the 10 MeV/u cocktail is in progress and has been accelerated through the 88-Inch cyclotron. This paper presents the latest work towards integrating the VENUS ion source into our research and operational goals.
	Slides THXO02 [8.391 MB]

THXO03	Recent RIKEN 28 GHz SC-ECRIS Results	159
	Y. Higurashi, M. Fujimaki, H. Haba, O. Kamigaito, M. Kidera, M. Komiyama, J. Ohnishi, K. Ozeki RIKEN Nishina Center, Wako, Japan T. Aihara, M. Tamura, A. Uchiyama SHI Accelerator Service Ltd., Tokyo, Japan
	For increasing the beam intensity of highly charged heavy ions at RIKEN RIBF, we constructed new SC-ECR ion source. In the spring of 2011, we injected 28GHz microwave into the ion source and obtained first beam. Since then, we made several test experiments for increasing the beam intensity of highly charged Xe and U ion beam, and produced ~60 eμA of U³⁵⁺, ~90 eμA of U³³⁺ at the injected RF power of ~2 kW using sputtering method. In case of Xe²⁵⁺, 250 euA was obtained at RF power of 1.7 kW. Using sputtering method, we produced U³⁵⁺ ion beam longer than one month for the RIBF experiment without break. In the beginning of 2012, we installed additional GM-JT refrigerator to increase the cooling power at 4.2 K, then the total cooling power became higher than 9 W. Using it, we can use higher than 8 W of cooling power for heat load due to the absorbed X-rays. In this summer, we will install the new plasma chamber made of Al for increasing the cooling power. We will also use high temperature oven to increase the U vapor. In this contribution, we report the recent modification of the ion source and test experiments for production of U and Xe ion beam.
	Slides THXO03 [49.487 MB]

THXO04	SECRAL status and future challenge
	H.W. Zhao, W. Lu, L.T. Sun, D. Xie, X.Z. Zhang IMP, Lanzhou, People's Republic of China
	SECRAL, the superconducting ECR ion source at IMP, has been in routine operation for the HIRFL accelerator complex since May 2007. The total operation beam time provided by SECRAL has so far exceeded 9500 hours. In most cases SECRAL has been operating at 18 GHz for the accelerator complex, and only operating at 24 GHz for the very high charge states and very heavy ion beams such as Bi and U beams. Uranium beam was tested at 24 GHz with ion sputtering in which 160 eμA of ²³⁸U³³⁺ was produced, and ²³⁸U³²⁺ beam was delivered to the accelerator continuously for almost one month. Beam long-term stability and emittance at high rf power of 24 GHz were studied. The operation status and the latest performance of SECRAL ion source will be presented. A new heavy ion accelerator facility HIAF has been proposed at IMP. HIAF requests an ion source capable of producing a pulse beam of 2.0 emA of ²³⁸U³⁴⁺. A next generation superconducting ECR ion source with operating frequency up to 50-60 GHz is under consideration in which a few options for the superconducting magnet configuration are being studied. Technical challenges for the next generation ECR ion source will be reviewed.
	Slides THXO04 [12.086 MB]