RFQ Posters at EPAC2002, Paris
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Transcript of RFQ Posters at EPAC2002, Paris
RFQ Posters at EPAC2002, Paris
Alan Letchford, ISIS Accelerator Division, Linac Group
A summary of Radio Frequency Quadrupole
accelerator work as presented at the
poster sessions of the 8th European Particle
Accelerator Conference, Cité des Sciences, Paris, June
2002.
What is an RFQ accelerator?
The principles of operation of the RFQ where first presented by two scientists from ITEP Moscow in the former Soviet Union (now Russia)
I.M. Kapchinsky & V.A. TeplyakovLinear ion acceleration with spatially homogeneous strong focussingPrib. Tekh. Eksp. No.2 pp19-22 (1970)
First practical RFQ was realised by LANL (then LASL) in 1980. Much development occurred around this time in the USA driven by SDI (Star Wars)
The Quadrupole Lens
+
-
+
-
N S
NS
Magnetic Quadrupole Lens
Electric Quadrupole Lens
Focusing in one plane, de-focusing in the other
Alternating Gradient Focusing
F D F D F
D F D F D
Net focusing can be achieved by a system of focusing and defocusing elements
Radio Frequency Quadrupole
F F
F F
F
D D D F
D D D
Why an RFQ?
Magnetic quadrupoleforce:
Fx = -q B0 x aFy = +q B0 y a
Electric quadrupoleforce:
Fx = -qV0 x a2
Fy = +qV0 y a2
Ek = 35 keV = 0.0086 cRequired pole tip field fora = 5 mm, B0 = 3.5T
E.g. ISIS RFQ input:
V0 = 45 kV, a = 5 mm
Very high!
RFQ with acceleration
Vertical electrodes
Horizontal electrodes
3D focusing and accelerating field
Vertical electrode
Horizontal electrodeQuadrupole focusing field
Axial acceleration field
RFQ accelerator
Vertical force
Horizontal force
Axial force (acceleration)
ISIS RFQ structure
Electrode support assembly
ISIS RFQ structure
Electrode support assembly with electrodes
ISIS RFQ structure
Electrode detail
ISIS RFQ structure
Electrode detail
ISIS RFQ structure
Vacuum vessel and RF feed loop
Completed ISIS RFQ
ISIS EHT area, LEDS and RFQ test stand
RFQ posters at EPAC2002www.cern.ch/EPAC
34 Posters with RFQ keyword
Superconducting RFQ's Ready for Ion Beam Operation at INFN-Legnaro G. Bisoffi, V. Andreev, G. Bassato, G.P. Bezzon, S. Canella, F. Chiurlotto, A. Lombardi, A.M. Porcellato, INFN-LNL, Legnaro, Padova; E. Chiaveri, CERN, Geneva; W. Singer, DESY, Hamburg; T. Shirai, ICR, Kyoto; S.Y. Stark, Strumenti Scientifici, CINEL,
Vigonza, Padova Status Report on the Construction of the French High Intensity Proton Injector (IPHI) P.-Y. Beauvais, CEA, Gif-sur-Yvette
Correction of Spherical Aberrations by a Partially Neutralized Beam Part for the
Injection of Ions into a RFQ R. Becker, IAP, Frankfurt-am-Main; M. Mücke, Singulus Technologies GmbH, Alzenau
Linac Complex in the JAERI-KEK Joint RNB Facility S. Arai, Y. Arakaki, K. Niki, M. Okada, Y. Takeda, M. Tomizawa, KEK, Ibaraki-ken; S. Takeuchi, JAERI, Ibaraki-ken
Results from the ISIS RFQ Test Stand C.P. Bailey, J.P. Duke, A.P. Letchford, J.W.G. Thomason, CLRC RAL, Chilton, Didcot
Exploring the Feasibility of a Separated Function RFQ Structure C.E. Chen, J.X. Fang, Z.Y. Guo, W.G. Li, X.Q. Yan, IHIP, Beijing; Y. Wu, IPP, Hefei
Design of a 200MHz Proton RFQ Z.Y. Guo, C.E. Chen, J.X. Fang, Y.R. Lu, X.Q. Yan, C. Zhang, IHIP, Beijing
Injection into RFQ Using Beams with Different Energies V. Kapin, K. Noda, NIRS, Chiba City
New Potential Function for RFQ Accelerator Cells S. Koscielniak, TRIUMF, Vancouver
Development of a FDT-Cavity K.-U. Kuehnel, A. Schempp, IAP, Frankfurt-am-Main
RFQ posters at EPAC2002 Field Tuning of the TRASCO RFQ G. Lamanna, INFN-Bari, Bari; S. Fu, H.F. Ouyang, IHEP, Beijing; A. Palmieri, A. Pisent, INFN-LNL, Legnaro, Padova
Measured Performance of the ISIS RFQ A.P. Letchford, C.P. Bailey, J.P. Duke, D.J.S. Findlay, J.W.G. Thomason, CLRC RAL, Chilton, Didcot
Electromagnetic Design of an 80.5 MHz RFQ for the RIA Driver Linac H. Podlech, U. Ratzinger, IAP, Frankfurt-am-Main; D. Gorelov, W. Hartung, F. Marti, X. Wu, R.C. York, NSCL, East Lansing
RIA RFQ Beam Dynamic Studies H. Podlech, U. Ratzinger, IAP, Frankfurt-am-Main; D. Gorelov, W. Hartung, F. Marti, X. Wu, R.C. York, NSCL, East Lansing
Design of a 40 MHz RFQ for a Post Accelerator at the Coupled Cyclotron Facility at
NSCL H. Podlech, IAP, Frankfurt-am-Main; D. Gorelov, W. Hartung, F. Marti, X. Wu, R.C. York, NSCL, East Lansing
Theoretical Analysis of a Real-life RFQ Using a 4-Wire Line Model and the Theory of
Differential Operators F. Simoens, A. France, CEA, Gif-sur-Yvette
A New RFQ Model Applied to the Estimation of Mechanical Defaults Distribution F. Simoens, A. France, J. Gaiffier, CEA, Gif-sur-Yvette
A Fully Automated Test Bench for the Measurement of the Field Distribution in RFQ
and Other Resonant Cavity F. Simoens, F. Ballester, A. France, J. Gaiffier, A. Sinanna, CEA, Gif-sur-Yvette
Funneling with the Two-beam RFQ H. Zimmermann, A. Bechtold, A. Schempp, J. Thibus, IAP, Frankfurt-am-Main
Commissioning of the SNS Front-End Systems at Berkeley Lab R. Keller, J.J. Ayers, L. Doolittle, J.B. Greer, S. Lewis, C. Lionberger, M. Monroy, J. Pruyn, A. Ratti, J.W. Staples, D. Syversrud, R.W. Thomae, LBNL, Berkeley; A. Aleksandrov, T. Shea, ORNL, Oak Ridge
Ion Beam Buffer Gas Cooling by a RF-Quadrupole E. Vassilakis, A. Schempp, IAP, Frankfurt-am-Main
RFQ posters at EPAC2002 Electromagnetic Characterization of the First IPHI RFQ Section F. Simoens, A. France, J. Gaiffier, CEA, Gif-sur-Yvette
Beams Dynamics End to End Simulations in IFMIF Linac R. Duperrier, R. Ferdinand, N. Pichoff, D. Uriot, CEA, Gif-sur-Yvette
A New Experimental Approach to Space Charge Effects H. Okamoto, K. Ito, R. Takai, Y. Wada, Hiroshima University, Higashi-Hiroshima
Synchrobetatron Dynamics with a Radio Frequency Quadrupole A.A. Valishev, E.A. Perevedentsev, BINP, Novosibirsk
BRICTEST: A Code for Charge Breeding Simulations V. Variale, INFN-Bari, Bari; M. Claudione, T. Clauser, A. Raino', Universita' di Bari e INFN-Bari, Bari
The RFQ Test Stand Ion Source at RAL J.W.G. Thomason, P.J.S. Barratt, C.J. Barton, J.C. Kerr, C.R. Lambourne, A.P. Letchford, G.R. Murdoch, M. Perkins, J. Saunders, R. Sidlow, C.P. Viswanathan, M.O. Whitehead, CLRC RAL, Chilton, Didcot
Measurements of Beam Energy using the Gas Scattering System in the ISIS RFQ Test Stand J.P. Duke, D.J.S. Findlay, S. Hughes, P. Knight, G.R. Murdoch, CLRC RAL, Chilton, Didcot
A New Structure combining Low Dimensions of the Four Rods and Technical Advantages of the Four Vanes M. Painchault, R. Duperrier, CEA, Gif-sur-Yvette
High Power RF System for KOMAC RFQ Y.-S. Cho, B.-H. Choi, J.-M. Han, H.-J. Kwon, KAERI, Daejon
Status of the Vacuum System for the IPHI Project N. Rouvière, F. Dubois, R. Leplat, L. Vatrinet, IPN, Orsay; R. Gobin, F. Harrault, P.A. Leroy, CEA, Gif-sur-Yvette
Design and Construction of an RFQ-Drifttube-Combination for a Medicine Synchrotron A. Bechtold, U. Ratzinger, A. Schempp, IAP, Frankfurt-am-Main; B. Schlitt, GSI, Darmstadt
Development and Construction of Experimental ADS at ITEP A.M. Kozodaev, N.D. Gavrilin, V.N. Konev, N.V. Lazarev, D.A. Liakin, A.M. Raskopin, B.Yu. Sharkov, O.V. Shvedov, E.B. Volkov, ITEP, Moscow
COMMISSIONING OF THE SNS FRONT-END SYSTEMS AT BERKELEY LAB
R. Keller, J.J. Ayers, L. Doolittle, J.B. Greer, S. Lewis, C. Lionberger, M. Monroy, J. Pruyn, A. Ratti, J.W. Staples, D. Syversrud, and R. Thomae
Ernest Orlando Lawrence Berkeley National Laboratory, Berkeley, CA, USAA. Aleksandrov for the SNS Accelerator Physics Group and T. Shea for the SNS Diagnostics
Collaboration
AbstractConstruction of a 2.5-MeV linac injector, the Front-End (FE) for the Spallation Neutron Source (SNS) project, was completed in the spring of 2002. Of the major FE subsystems, the rf-driven H- ion source, the electrostatic LEBT, and the first of four RFQ modules had been commissioned by the spring of 2001, and commissioning of the remaining RFQ modules as well as the full system including the elaborate MEBT was carried out in Jan. through May, 2002. The Front End will be shipped to Oak Ridge, starting in June, 2002, and re-commissioned after installation at the SNS site. This paper gives an overview of FE major design features and experimental results obtained during the commissioning process at LBNL.
COMMISSIONING OF THE SNS FRONT-END SYSTEMS AT BERKELEY LAB
STATUS REPORT ON THE CONSTRUCTION OF THE FRENCH HIGH INTENSITY PROTON
INJECTOR (IPHI). P-Y Beauvais for the CEA and CNRS IPHI team, CEA Saclay, DSM/DAPNIA 91191 Gif sur Yvette
Cedex Abstract In 1997, the two French National Research Agencies (CEA and CNRS) decided to collaborate in order to study and construct a prototype of the low energy part of a High Power Proton Accelerator (HPPA). The main objective of this project (the IPHI project), is to allow the French team to master the complex technologies used and the control concepts of the HPPAs. The applications of such accelerators are numerous : Accelerator Driven Systems, irradiation tool, condensed matter studies, radioactive beam, muon or neutrino production. This demonstration linear accelerator, the assembly of which is presently in progress on the Saclay site, could reach in a final state a power of more than 1 MW for an energy of about 10 MeV (not presently funded). In a first step, the energy beam will be limited to 5 MeV. This paper reports on the state of the construction and assembly of IPHI. The planning of assembly and starting is also presented.
STATUS REPORT ON THE CONSTRUCTION OF THE FRENCH HIGH INTENSITY PROTON
INJECTOR (IPHI).
LINAC COMPLEX IN THE JAERI-KEK JOINT RNB FACILITY
S. Arai, Y. Arakaki, K. Niki, M. Okada, Y. Takeda, M. Tomizawa, KEK, Ibaraki-ken, Japan S. Takeuchi, JAERI, Ibaraki-ken, Japan
Abstract Construction of the JAERI-KEK joint RNB facility has started from 2001 at JAERI-Tokai tandem site. In the first stage, the facility comprises a tandem accelerator, an isotope-separator on line and a linac complex. The radioactive nuclear beams (RNBs) are produced by a 36-MeV 3-µA proton beam from tandem accelerator. The linac complex comprises a 26-MHz split coaxial RFQ and a 52-MHz interdigital-H (IH) linac. The beam energy is available in the range of 0.14 to 1.09 MeV/u. In the second stage, the RFQ/IH linac is connected to the JAERI superconducting tandem booster linac by adding a 2-MeV/u linac between them. The extended linac complex can provide the maximum beam energies of 5 Mev/u for q/A=1/7 ions and 8 MeV/u for q/A=1/4 ions.
LINAC COMPLEX IN THE JAERI-KEK JOINT RNB FACILITY
FUNNELING WITH THE TWO-BEAM RFQ
H. Zimmermann, A. Bechtold, A. Schempp, J. ThibusInstitut für Angewandte Physik, Johann Wolfgang Goethe-Universität,
Robert-Mayer-Straße 2-4, D-60325 Frankfurt am Main, GermanyAbstractNew high current accelerator facilities like proposed for ESS requires a beam with a very high brilliance. These beams can not be produced by a single ion-source. The increase in brightness in the driver linac is done by several funneling stages at low energies, in which two identically bunched ion beams are combined into a single beam with twice the frequency, current and brightness. Our Two-Beam-RFQ funneling experiment is a set-up of two ion sources, a Two-Beam-RFQ, two different funnel deflectors and beam diagnostic equipment to demonstrate funneling of ion beams as a model for the funneling stage for the ESS driver. The progress of the funneling experiment and results of simulations will be presented.
FUNNELING WITH THE TWO-BEAM RFQ
THE RFQ TEST STAND ION SOURCE AT RAL
J. W. G. Thomason, P. J. S. Barratt, C. J. Barton, J. C. Kerr, C. R. Lambourne, A. P. Letchford, G. R.Murdoch, M. Perkins, J. Saunders, R. Sidlow, C. P. Viswanathan and M. O. Whitehead, CLRC
RAL, Didcot, Oxon, UK
AbstractThe RFQ test stand at Rutherford Appleton Laboratory (RAL) is now being operated with an ion source identical to that used on ISIS. This is a surface plasma ion source of the Penning type, and on ISIS routinely produces 35mA of H- ions during a 200 µs pulse at 50 Hz for uninterrupted periods of up to 50 days. A new ion source vacuum chamber which is compatible with the low energy beam transport system for the RFQ has been constructed, and the layout of power supplies and other essential services have been reconfigured in order toensure that the RFQ will fit the space available when it is eventually installed on ISIS. An extensive redesign of many power supplies, where exact duplication of the ISIS equipment has proved impossible because of component obsolescence, has been necessary. In addition a new timing system and control systems using fibre optic ethernet have been developed specifically for this application.
THE RFQ TEST STAND ION SOURCE AT RAL
MEASUREMENTS OF BEAM ENERGY USING THE GAS SCATTERING
SYSTEM IN THE ISIS RFQ TEST STANDJ P Duke, D J S Findlay, S Hughes, P Knight, G R Murdoch, CLRC, RAL, Chilton, Didcot
AbstractThe new RFQ accelerator for the ISIS Spallation Neutron Source at the Rutherford Appleton Laboratory (RAL) is designed to accelerate H– particles from 35 keV to 665 keV. Beams have already been successfully accelerated through the RFQ, and now investigations are continuing into the detailed properties of the accelerated beam using the RFQ Test Stand at RAL. A novel system has been set up in which the beam of accelerated particles is attenuated in cascaded multiple scattering cells filled with xenon gas and the energies of the particles are measured using a semiconductor particle detector. Measurements and results are reported.
MEASUREMENTS OF BEAM ENERGY USING THE GAS SCATTERING
SYSTEM IN THE ISIS RFQ TEST STAND
MEASURED PERFORMANCE OF THE ISIS RFQ
A.P. Letchford, C.P. Bailey, J.P. Duke, D.J.S. Findlay, J.W.G. Thomason, CLRC RAL, Didcot, UK
AbstractThe ISIS RFQ is a 665 keV, 202.5 MHz, 4-rod RFQ intended as a replacement pre-injector for the ISIS spallation neutron source at RAL. A test facility has been constructed for soak testing and characterising of the RFQ before installation. Results are presented for measurements of the principal parameters of the RFQ together with its performance characteristics. A comparison is made between the measurements and the results from computer simulations.
MEASURED PERFORMANCE OF THE ISIS RFQ
MEASURED PERFORMANCE OF THE ISIS RFQ
LEBT Emittances
MEASURED PERFORMANCE OF THE ISIS RFQ
Measured
Calculated
Output Emittances
ElectrodeVoltage
Measured PeakEnergy
Calculated PeakEnergy
80 kV 661 keV 661 keV
85 kV 665 keV 663 keV
90 kV 670 keV 669 keV
Final Energy