Presentation is loading. Please wait.

Presentation is loading. Please wait.

Finemet cavity impedance studies

Published bySheryl Chandler Modified over 6 years ago

Similar presentations

Presentation on theme: "Finemet cavity impedance studies"— Presentation transcript:

1 Finemet cavity impedance studies
Serena Persichelli PS-LIU meeting Acknowledgements Simone Gilardoni Mauro Migliorati Mauro Paoluzzi Benoit Salvant

2 Aim of the study The aim of the study is to evaluate the impedance excited in the Finemet cavity by a bunch with the same length of the PS bunches (26 cm - 12m) Time domain simulations with CST Particle Studio have been performed in order to get the longitudinal impedance of the cavity and make a comparison with the measured longitudinal impedance The study has been performed on simplified 3D geometries imported from a mechanical CATIA drawing, assuming small impact on the final results. The Finemet cavity has been simulated starting with the one cell model (the one that has also been measured) but also the cavity complete model with six cells has been studied The dispersive material has been defined in CST with a dispersion model starting from the measurements of the μ’ and μ’’ parameters performed for Finemet by Mauro Paoluzzi .

3 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

4 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

5 Finemet 1-cell cavity design for CST simulations
Perfectly conducting walls Finemet Copper Alumina NB. The design considered for CST simulations has been simplify from the original mechanical model!

6 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

7 1-cell cavity without Finemet
Longitudinal impedance Bunch length 260 mm Wake length 800 m fMAX 700 MHz # of mesh 356,000 Method Indirect test beam In the longitudinal and transverse impedance one can identify a mode trapped around 208 MHz. This mode will be dump by the insertion of the Finemet rings!

8 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

9 CST Finemet fitting (1st order): version 2012
Fitting of μ’ used for simulations

10 CST Finemet fitting (1st order): version 2012
Fitting of μ’' used for simulations

11 Comparison between measurement and simulation
Longitudinal impedance Bunch length 90 cm Wake length 600 m fMAX 200 MHz # of mesh Method Direct Because of the imprecise fitting of the dispersion parameters in CST 2012, the impedance obtained few month ago was not in perfect agreement with measurements The differences between the two curves are due to the poor resolution at low frequencies and to the Direct integration method that has been used

12 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

13 CST Finemet fitting (nth order): version 2013
Fitting of μ’ used for simulations

14 CST Finemet fitting (nth order): version 2013
Fitting of μ’' used for simulations εr=25

15 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

16 Wakefield CST Particle Studio analysis
Longitudinal wake potential Bunch length 260 cm Wake length 700 m fMAX 700 MHz # of mesh 98,175 Method Indirect test beam NB. This model of longitudinal wake potential can be used for Headtail simulations

17 Wakefield CST Particle Studio analysis
Electric field monitor All the modes of the pillbox cavity are strongly dumped by the Finemet rings: we predict to have no issues regarding trapped or parasitic modes in the cavity

18 Comparison between measurement and simulation
Longitudinal impedance: real part Bunch length 90 cm Wake length 600 m fMAX 200 MHz # of mesh Method Indirect test beam Results obtained with CST 2013 show a good agreement with the measured impedance! This improvement in resolution at low frequencies has been obtained thank to a better fitting of the dispersion parameters and to the use of the Indirect test beam integration method

19 Comparison between measurement and simulation
Longitudinal impedance: imaginary part Bunch length 90 cm Wake length 600 m fMAX 200 MHz # of mesh Method Indirect test beam Results obtained with CST 2013 show a good agreement with the measured impedance! This improvement in resolution at low frequencies has been obtained thank to a better fitting of the dispersion parameters and to the use of the Indirect test beam integration method

20 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

21 Finemet 6-cell cavity design for CST simulations
Few moths ago we had several problem in the model because of the errors encountered during import from CATIA. These problems were source of loss of resolution but they have been solved on the new model!

22 Agenda Finemet cavity: one-cell model Finemet cavity: six-cells model
Design for simulation 1-cell cavity without Finemet CST Finemet fitting (1st order): version 2012 CST Finemet fitting (nth order): version 2013 Wakefield CST Particle Studio analysis Longitudinal wake potential Comparison between measurements and simulations Finemet cavity: six-cells model Design for simulations

23 Wakefield CST Particle Studio analysis
Longitudinal wake potential Bunch length 50 cm Wake length 800 m fMAX 345 MHz # of mesh 3,000,816 Method Indirect test beam NB. This model of longitudinal wake potential can be used for Headtail simulations

24 Wakefield CST Particle Studio analysis
Electric field monitor All the modes of the pillbox cavity are strongly dumped by the Finemet rings: we predict to have no issues regarding trapped or parasitic modes in the cavity

25 Comparison between measurement and simulation
Longitudinal impedance: real part Bunch length 50 cm Wake length 800 m fMAX 354 MHz # of mesh 3,000,816 Method Indirect test beam Results obtained with CST 2013 show a good agreement with the measured impedance! The blue curve was obtained multiplying by a factor 6 the data from measurement of the 1-cell cavity

26 Comparison between measurement and simulation
Longitudinal impedance: imaginary part Bunch length 50 cm Wake length 800 m fMAX 354 MHz # of mesh 3,000,816 Method Indirect test beam Results obtained with CST 2013 show a good agreement with the measured impedance! The blue curve was obtained multiplying by a factor 6 the data from measurement of the 1-cell cavity

27 Conclusions From simulations performed with two different versions of CST Particle Studio we can confirm that the impedance observed with measurements can be exited by bunches circulating in the PS. In the six-cell cavity, a circulating bunch can excite a longitudinal impedance that has a maximum of 2 kΩ around 4 MHz on the real part, that also correspond to the zero crossing of the imaginary part curve. The same mode seems to be produced also on the transverse plane: more investigations with the new SCT version are needed . All the eigenmodes of the cavity are strongly dumped by the Finemet rings: we predict to have no issues regarding trapped or parasitic modes in the Finemet cavity. Improvements of the quality of simulation have been obtained thanks to a better fitting of the dispersion parameters of CST version 2013 and thanks to the use of an indirect integration method that is more accurate that the direct method used few months ago. .

Download ppt "Finemet cavity impedance studies"

Similar presentations

D. Lipka, MDI, DESY Hamburg, July 2012 Simulation of fields around spring and cathode for photogun D. Lipka, MDI, DESY Hamburg.

D. Lipka, MDI, DESY Hamburg, July 2012 Simulation of fields around spring and cathode for photogun D. Lipka, MDI, DESY Hamburg.
Impedance of SPS travelling wave cavities (200 MHz) A. Grudiev, E. Métral, B. Salvant, E. Shaposhnikova, B. Spataro Acknowledgments: Erk Jensen, Eric Montesinos,

Impedance of SPS travelling wave cavities (200 MHz) A. Grudiev, E. Métral, B. Salvant, E. Shaposhnikova, B. Spataro Acknowledgments: Erk Jensen, Eric Montesinos,
Impedance of new ALICE beam pipe Benoit Salvant, Rainer Wanzenberg and Olga Zagorodnova Acknowledgments: Elias Metral, Nicolas Mounet, Mark Gallilee, Arturo.

Impedance of new ALICE beam pipe Benoit Salvant, Rainer Wanzenberg and Olga Zagorodnova Acknowledgments: Elias Metral, Nicolas Mounet, Mark Gallilee, Arturo.
Calculations of wakefields for the LHCb VeLo. Olga Zagorodnova Desy Hamburg April 29, 2015 1.

Calculations of wakefields for the LHCb VeLo. Olga Zagorodnova Desy Hamburg April 29,
Introduction Status of SC simulations at CERN

Introduction Status of SC simulations at CERN
Particle Studio simulations of the resistive wall impedance of copper cylindrical and rectangular beam pipes C. Zannini E. Metral, G. Rumolo, B. Salvant.

Particle Studio simulations of the resistive wall impedance of copper cylindrical and rectangular beam pipes C. Zannini E. Metral, G. Rumolo, B. Salvant.
TDI longitudinal impedance simulation with CST PS A.Grudiev 20/03/2012.

TDI longitudinal impedance simulation with CST PS A.Grudiev 20/03/2012.
Acknowledgements F. Caspers, H. Damerau, M. Hourican, S.Gilardoni, M. Giovannozzi, E. Métral, M. Migliorati, B. Salvant Dummy septum impedance measurements.

Acknowledgements F. Caspers, H. Damerau, M. Hourican, S.Gilardoni, M. Giovannozzi, E. Métral, M. Migliorati, B. Salvant Dummy septum impedance measurements.
Agenda: General kickers analysis Wang-Tsutsui method for computing impedances Benchmarks Conclusions Bibliography Acknowledgments: E.Métral, M.Migliorati,

Agenda: General kickers analysis Wang-Tsutsui method for computing impedances Benchmarks Conclusions Bibliography Acknowledgments: E.Métral, M.Migliorati,
Outline: Motivation The Mode-Matching Method Analysis of a simple 3D structure Outlook Beam Coupling Impedance for finite length devices N.Biancacci, B.Salvant,

Outline: Motivation The Mode-Matching Method Analysis of a simple 3D structure Outlook Beam Coupling Impedance for finite length devices N.Biancacci, B.Salvant,
Status of the PSB impedance model C. Zannini and G. Rumolo Thanks to: E. Benedetto, N. Biancacci, E. Métral, N. Mounet, T. Rijoff, B. Salvant.

Status of the PSB impedance model C. Zannini and G. Rumolo Thanks to: E. Benedetto, N. Biancacci, E. Métral, N. Mounet, T. Rijoff, B. Salvant.
Update of the SPS transverse impedance model Benoit for the impedance team.

Update of the SPS transverse impedance model Benoit for the impedance team.
IMPEDANCE OF Y-CHAMBER FOR SPS CRAB CAVITY By Phoevos Kardasopoulos Thanks to Benoit Salvant, Pei Zhang, Fred Galleazzi, Roberto Torres-Sanchez and Alick.

IMPEDANCE OF Y-CHAMBER FOR SPS CRAB CAVITY By Phoevos Kardasopoulos Thanks to Benoit Salvant, Pei Zhang, Fred Galleazzi, Roberto Torres-Sanchez and Alick.
Status of PSB Impedance calculations: Inconel undulated chambers C. Zannini, G. Rumolo, B. Salvant Thanks to: E. Benedetto, J. Borburgh.

Status of PSB Impedance calculations: Inconel undulated chambers C. Zannini, G. Rumolo, B. Salvant Thanks to: E. Benedetto, J. Borburgh.
Elias Métral, LHC Beam Commissioning Working Group meeting, 08/06/2010 /191 SINGLE-BUNCH INSTABILITY STUDIES IN THE LHC AT 3.5 TeV/c Elias Métral, N. Mounet.

Elias Métral, LHC Beam Commissioning Working Group meeting, 08/06/2010 /191 SINGLE-BUNCH INSTABILITY STUDIES IN THE LHC AT 3.5 TeV/c Elias Métral, N. Mounet.
Update on BGV impedance studies Alexej Grudiev, Berengere Luthi, Benoit Salvant for the impedance team Many thanks to Bernd Dehning, Massimiliano Ferro-Luzzi,

Update on BGV impedance studies Alexej Grudiev, Berengere Luthi, Benoit Salvant for the impedance team Many thanks to Bernd Dehning, Massimiliano Ferro-Luzzi,
Calculations of wakefields for the LHCb VeLo. Olga Zagorodnova Desy Hamburg April 8, 2015 1.

Calculations of wakefields for the LHCb VeLo. Olga Zagorodnova Desy Hamburg April 8,
Update on wire scanner impedance studies

Update on wire scanner impedance studies
Chromaticity dependence of the vertical effective impedance in the PS Chromaticity dependence of the vertical effective impedance in the PS S. Persichelli.

Chromaticity dependence of the vertical effective impedance in the PS Chromaticity dependence of the vertical effective impedance in the PS S. Persichelli.
CST Particle studio. Analysis of “STEP-OUT” Olav Berrig Thanks to Benoit Salvant.

CST Particle studio. Analysis of “STEP-OUT” Olav Berrig Thanks to Benoit Salvant.

Similar presentations

Ads by Google