Cyclotrons2013 - List of Authors (Brandenburg, S.)

Paper

Title

Page

Improving the Energy Efficiency, Reliability and Performance of AGOR

25

M.A. Hofstee, S. Brandenburg, H. Post, R.A. Schellekens, J.E. de Jong
KVI, Groningen, The Netherlands

Over the past few years the nature of the experiments performed with AGOR has changed from long experiments, to sequences of short experiments, often using different beams. In addition the total demand for beamtime has gone down. This has required a change in operating procedures and scheduling. In view of the changing demands, we are continuing our efforts to improve the energy efficiency and reliability of the cyclotron, while at the same time trying to improve performance. While some of the solutions might be unique to our facility, many will have broader applicability. Some case studies will be presented and areas for future improvements identified.

Slides MO2PB04 [2.578 MB]

WEPPT009

Transverse Phase-Space Distributions of Low Energy Ion Beams Extracted from an ECR Ion Source

341

S. Saminathan
TRIUMF, Canada's National Laboratory for Particle and Nuclear Physics, Vancouver, Canada
J.P.M. Beijers, S. Brandenburg, H.R. Kremers, V. Mironov
KVI, Groningen, The Netherlands

Transverse phase-space distributions of low-energy ion beams extracted from ECR ion sources often show higher-order effects caused by ion-optical aberrations. Understanding these effects is mandatory to keep emittance growth and the resulting beam losses in low-energy beam transport lines under control. We present the results of an experimental and theoretical study of beam extraction and transport in the AGOR injection line at KVI. Particle tracking simulations have been performed of a multi-component neon ion beam extracted from an ECR ion source to calculate 4D phase-space distributions at various positions along the beamline. The simulations compare well with beam profile and emittance measurements.

WE3PB04

Transmission of Heavy Ion Beams in the AGOR Cyclotron

420

A. Sen, S. Brandenburg, M.A. Hofstee
KVI, Groningen, The Netherlands
M.J. van Goethem
UMCG, Groningen, The Netherlands

During the acceleration of intense low energy heavy ion beams in the AGOR cyclotron feedback between beam intensity and pressure, driven by beam loss induced desorption, is observed. This feedback limits the attainable beam intensity. Calculations and measurements of the pressure dependent transmission for various beam agree reasonably well. Calculation of the trajectories of ions after a charge change shows that the desorption is mainly due to ions with near extraction energies, hitting the outer wall at a shallow angle of incidence. For heavy ions like ²⁰⁶Pb²⁷⁺ several charge exchanges are needed before the orbit becomes unstable. Our calculations indicate that these ions make thousands of turns before finally hitting the wall. They therefore are a large fraction of the circulating ions and may contribute to vacuum degradation through restgas ionization. Ion induced desorption for relevant ions and materials has been measured; it explains the observations in the cyclotron semi-quantitatively.
This work has been financially supported by the Foundation FOM, the Dutch funding agency NWO and the EU-FP7, Grant Agreement n° 262010 - ENSAR.

Slides WE3PB04 [5.272 MB]

Paper	Title	Page
MO2PB04	Improving the Energy Efficiency, Reliability and Performance of AGOR	25
	M.A. Hofstee, S. Brandenburg, H. Post, R.A. Schellekens, J.E. de Jong KVI, Groningen, The Netherlands
	Over the past few years the nature of the experiments performed with AGOR has changed from long experiments, to sequences of short experiments, often using different beams. In addition the total demand for beamtime has gone down. This has required a change in operating procedures and scheduling. In view of the changing demands, we are continuing our efforts to improve the energy efficiency and reliability of the cyclotron, while at the same time trying to improve performance. While some of the solutions might be unique to our facility, many will have broader applicability. Some case studies will be presented and areas for future improvements identified.
	Slides MO2PB04 [2.578 MB]

WEPPT009	Transverse Phase-Space Distributions of Low Energy Ion Beams Extracted from an ECR Ion Source	341
	S. Saminathan TRIUMF, Canada's National Laboratory for Particle and Nuclear Physics, Vancouver, Canada J.P.M. Beijers, S. Brandenburg, H.R. Kremers, V. Mironov KVI, Groningen, The Netherlands
	Transverse phase-space distributions of low-energy ion beams extracted from ECR ion sources often show higher-order effects caused by ion-optical aberrations. Understanding these effects is mandatory to keep emittance growth and the resulting beam losses in low-energy beam transport lines under control. We present the results of an experimental and theoretical study of beam extraction and transport in the AGOR injection line at KVI. Particle tracking simulations have been performed of a multi-component neon ion beam extracted from an ECR ion source to calculate 4D phase-space distributions at various positions along the beamline. The simulations compare well with beam profile and emittance measurements.

WE3PB04	Transmission of Heavy Ion Beams in the AGOR Cyclotron	420
	A. Sen, S. Brandenburg, M.A. Hofstee KVI, Groningen, The Netherlands M.J. van Goethem UMCG, Groningen, The Netherlands
	During the acceleration of intense low energy heavy ion beams in the AGOR cyclotron feedback between beam intensity and pressure, driven by beam loss induced desorption, is observed. This feedback limits the attainable beam intensity. Calculations and measurements of the pressure dependent transmission for various beam agree reasonably well. Calculation of the trajectories of ions after a charge change shows that the desorption is mainly due to ions with near extraction energies, hitting the outer wall at a shallow angle of incidence. For heavy ions like ²⁰⁶Pb²⁷⁺ several charge exchanges are needed before the orbit becomes unstable. Our calculations indicate that these ions make thousands of turns before finally hitting the wall. They therefore are a large fraction of the circulating ions and may contribute to vacuum degradation through restgas ionization. Ion induced desorption for relevant ions and materials has been measured; it explains the observations in the cyclotron semi-quantitatively. This work has been financially supported by the Foundation FOM, the Dutch funding agency NWO and the EU-FP7, Grant Agreement n° 262010 - ENSAR.
	Slides WE3PB04 [5.272 MB]