Cyclotrons2013 - List of Keywords (cathode)

Paper	Title	Other Keywords	Page
TUPPT019	Development Study of Penning Ion Source for Compact 9 MeV Cyclotron	ion, electron, ion-source, plasma	195
	Y.H. Yeon, J.-S. Chai, T.V. Cong, Kh.M. Gad, M. Ghergherehchi, S.Y. Jung, H.S. Kim, H.W. Kim, S.H. Kim, S.H. Lee, Y.S. Lee, X.J. Mu, S.Y. Oh, S. Shin SKKU, Suwon, Republic of Korea
	Funding: This research was supported by WCU (World Class University) program through the National Research Foundation of Korea funded by the Ministry of Education, Science and Technology (R31-2008-10029). Penning Ion Gauge(PIG) have been used in internal source for cyclotron. PIG source for internal source of 9 MeV cyclotron produces H⁻ ion. This source consists of cold cathode which discharges electrons for producing H⁻ ion and anode for making plasma wall. Cold cathode material tantalum was used for emitting electrons and tungsten copper alloy was used for anode. The size of PIG source is related to size of cyclotron magnet. Optimization of cathode and anode location and sizing were needed for simplifying this source for reducing the size of compact cyclotron. Transportation of electrons and number of secondary electrons has been calculated by CST particle studio. Motion of H2 gas has been calculated by ANSYS. Calculation of PIG source in 9 MeV cyclotron has been performed by using various chimneys with different size of expansion gap between the plasma boundary and the chimney wall. In this paper design process and experiment result is reported.

TUPPT028	Development of 20 kW RF Amplifier for Compact Cyclotron	impedance, rf-amplifier, vacuum, cyclotron	212
	S.H. Lee, J.-S. Chai, T.V. Cong, H.S. Kim, Y.S. Lee, H.S. Song, Y.H. Yeon SKKU, Suwon, Republic of Korea J.H. Kim KIRAMS, Seoul, Republic of Korea
	Funding: This work was supported by Nuclear R&D program through the National Research Foundation of Korea funded by the Ministry of Education, Science and Technology. (2012-0925001) Compact cyclotron for PET RI production accelerates H⁻ ions using electric field. For accelerating ions in cyclotron, RF amplifier is developed to transmit RF power to RF resonating cavity. RF amplifier generates high-power RF signal up to 20 kW with narrow band frequency. The amplifier device was used of triode vacuum tube operated in cathode-driven. Impedance matching systems were composed of bridge-network system. Components of impedance matching system had rigid structure to endure high-power RF signal. Variable inductors of matching components have been used of short-bar movement system for changing reactance of characteristic impedance. The experiment results were measured by VSWR meter and network analyzer.

TUPPT030	Development of 1.5 kW RF Driver for Compact Cyclotron	impedance, vacuum, rf-amplifier, cyclotron	218
	H.S. Song, J.-S. Chai, T.V. Cong, S.Y. Jung, H.S. Kim, S.H. Lee, Y.S. Lee, S. Shin, Y.H. Yeon SKKU, Suwon, Republic of Korea J.H. Kim KIRAMS, Seoul, Republic of Korea
	1.5 kW RF driver is being designed and manufactured with the resonance frequency of 83.2 MHz. Triode (3CX1500A7) is used for RF power amplification, and ground grid amplifier (G.G. Amp.) type was adopted for this RF driver since the circuit design and realization is simple. Anode, and cathode voltage of RF driver is approximately 3500V, and 5V respectively. In this paper, impedance matching process of RF driver is described. Variable capacitor and variable inductor is utilized to implement the impedance matching for cathode and anode. In addition, RF power output characteristics compared with RF input is shown.

TU3PB01	Bunch-Shape Measurements at PSI’s High-power Cyclotrons and Proton Beam Lines	proton, cyclotron, electron, simulation	257
	R. Dölling PSI, Villigen PSI, Switzerland
	Longitudinal-transversal 2D-density distributions of the bunched 2.2 mA CW proton beam can now be measured at the 13 last turns of the Injector 2 cyclotron, at several locations in the connecting beam line to the Ring cyclotron, at the first two turns of the Ring cyclotron (all at energies around 72 MeV), as well as behind the Ring cyclotron (at 590 MeV). In the large part, distributions can be taken from several angles of view, separated each by 45°. The measurement systems at our facility have evolved with time; this paper gives the present status, performance, limits and typical results. Due to the limited space, we refer in the large part to our previous publications [1, 2, 3] and concentrate on recent findings and measurements and ideas for next steps.
	Slides TU3PB01 [9.393 MB]

WEPPT024	Rutgers 12-Inch Cyclotron: Dedicated to Training Through Research and Development	cyclotron, ion, ion-source, proton	366
	T.W. Koeth, J.E. Krutzler, T.S. Ponter, A.J. Rosenberg, W.S. Schneider Rutgers University, The State University of New Jersey, Piscataway, New Jersey, USA D.E. Hoffman PU, Princeton, New Jersey, USA
	The Rutgers 12-Inch Cyclotron is a 1.2 MeV proton accelerator dedicated to beam physics instruction.[1] The 12-inch cyclotron project began as a personal pursuit for two Rutgers undergraduate students in 1995 and was incorporated into the Modern Physics Teaching Lab in 2001.[2] Since then, student projects have been contributing to the cyclotron’s evolution through development of accelerator components. Most of the Rutgers 12-Inch Cyclotron components have been designed and built in house, thus giving its students a research and development introduction to the field of accelerator physics and associated hardware. [1] www.physics.rutgers.edu/cyclotron [2] T. Feder, “Building a Cyclotron on a Shoe String,” Physics Today, 30-31 (November 2004)

Paper

Title

Other Keywords

Page

TUPPT019

Development Study of Penning Ion Source for Compact 9 MeV Cyclotron

ion, electron, ion-source, plasma

195

Y.H. Yeon, J.-S. Chai, T.V. Cong, Kh.M. Gad, M. Ghergherehchi, S.Y. Jung, H.S. Kim, H.W. Kim, S.H. Kim, S.H. Lee, Y.S. Lee, X.J. Mu, S.Y. Oh, S. Shin
SKKU, Suwon, Republic of Korea

Funding: This research was supported by WCU (World Class University) program through the National Research Foundation of Korea funded by the Ministry of Education, Science and Technology (R31-2008-10029).
Penning Ion Gauge(PIG) have been used in internal source for cyclotron. PIG source for internal source of 9 MeV cyclotron produces H⁻ ion. This source consists of cold cathode which discharges electrons for producing H⁻ ion and anode for making plasma wall. Cold cathode material tantalum was used for emitting electrons and tungsten copper alloy was used for anode. The size of PIG source is related to size of cyclotron magnet. Optimization of cathode and anode location and sizing were needed for simplifying this source for reducing the size of compact cyclotron. Transportation of electrons and number of secondary electrons has been calculated by CST particle studio. Motion of H2 gas has been calculated by ANSYS. Calculation of PIG source in 9 MeV cyclotron has been performed by using various chimneys with different size of expansion gap between the plasma boundary and the chimney wall. In this paper design process and experiment result is reported.

TUPPT028

Development of 20 kW RF Amplifier for Compact Cyclotron

impedance, rf-amplifier, vacuum, cyclotron

212

S.H. Lee, J.-S. Chai, T.V. Cong, H.S. Kim, Y.S. Lee, H.S. Song, Y.H. Yeon
SKKU, Suwon, Republic of Korea
J.H. Kim
KIRAMS, Seoul, Republic of Korea

Funding: This work was supported by Nuclear R&D program through the National Research Foundation of Korea funded by the Ministry of Education, Science and Technology. (2012-0925001)
Compact cyclotron for PET RI production accelerates H⁻ ions using electric field. For accelerating ions in cyclotron, RF amplifier is developed to transmit RF power to RF resonating cavity. RF amplifier generates high-power RF signal up to 20 kW with narrow band frequency. The amplifier device was used of triode vacuum tube operated in cathode-driven. Impedance matching systems were composed of bridge-network system. Components of impedance matching system had rigid structure to endure high-power RF signal. Variable inductors of matching components have been used of short-bar movement system for changing reactance of characteristic impedance. The experiment results were measured by VSWR meter and network analyzer.

TUPPT030

Development of 1.5 kW RF Driver for Compact Cyclotron

impedance, vacuum, rf-amplifier, cyclotron

218

H.S. Song, J.-S. Chai, T.V. Cong, S.Y. Jung, H.S. Kim, S.H. Lee, Y.S. Lee, S. Shin, Y.H. Yeon
SKKU, Suwon, Republic of Korea
J.H. Kim
KIRAMS, Seoul, Republic of Korea

1.5 kW RF driver is being designed and manufactured with the resonance frequency of 83.2 MHz. Triode (3CX1500A7) is used for RF power amplification, and ground grid amplifier (G.G. Amp.) type was adopted for this RF driver since the circuit design and realization is simple. Anode, and cathode voltage of RF driver is approximately 3500V, and 5V respectively. In this paper, impedance matching process of RF driver is described. Variable capacitor and variable inductor is utilized to implement the impedance matching for cathode and anode. In addition, RF power output characteristics compared with RF input is shown.

TU3PB01

Bunch-Shape Measurements at PSI’s High-power Cyclotrons and Proton Beam Lines

proton, cyclotron, electron, simulation

257

R. Dölling
PSI, Villigen PSI, Switzerland

Longitudinal-transversal 2D-density distributions of the bunched 2.2 mA CW proton beam can now be measured at the 13 last turns of the Injector 2 cyclotron, at several locations in the connecting beam line to the Ring cyclotron, at the first two turns of the Ring cyclotron (all at energies around 72 MeV), as well as behind the Ring cyclotron (at 590 MeV). In the large part, distributions can be taken from several angles of view, separated each by 45°. The measurement systems at our facility have evolved with time; this paper gives the present status, performance, limits and typical results. Due to the limited space, we refer in the large part to our previous publications [1, 2, 3] and concentrate on recent findings and measurements and ideas for next steps.

Slides TU3PB01 [9.393 MB]

WEPPT024

Rutgers 12-Inch Cyclotron: Dedicated to Training Through Research and Development

cyclotron, ion, ion-source, proton

366

T.W. Koeth, J.E. Krutzler, T.S. Ponter, A.J. Rosenberg, W.S. Schneider
Rutgers University, The State University of New Jersey, Piscataway, New Jersey, USA
D.E. Hoffman
PU, Princeton, New Jersey, USA

The Rutgers 12-Inch Cyclotron is a 1.2 MeV proton accelerator dedicated to beam physics instruction.[1] The 12-inch cyclotron project began as a personal pursuit for two Rutgers undergraduate students in 1995 and was incorporated into the Modern Physics Teaching Lab in 2001.[2] Since then, student projects have been contributing to the cyclotron’s evolution through development of accelerator components. Most of the Rutgers 12-Inch Cyclotron components have been designed and built in house, thus giving its students a research and development introduction to the field of accelerator physics and associated hardware.
[1] www.physics.rutgers.edu/cyclotron
[2] T. Feder, “Building a Cyclotron on a Shoe String,” Physics Today, 30-31 (November 2004)