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Ranjan, K.

Paper Title Page
WEPEC009 Designing of 9 Cell Reduced Beta Elliptical Cavity for High Intensity Proton Linac 2908
 
  • A. Saini
    University of Delhi, Delhi
  • C.S. Mishra, K. Ranjan, N. Solyak, V.P. Yakovlev
    Fermilab, Batavia
 
 

A superconducting rf cavity is designed for acceleration of particles travelling at 81% the speed of light. The cavity will operate at 1.3 GHz & is to be used in SILC section of the proposed high intensity proton linac at Fermilab. At present cavity will serve to accelerate the particles for energy range 466 MeV to 1.2 GeV. The cavity will be shorter than 9 cell beta =1 cavity but nearly same ratio of surface magnetic field to surface electric field. Cell to cell coupling coefficient is also optimized to get the good field flatness. The cavity is studied for monopole modes and higher order modes. The shapes of end cells are optimized to avoid dangerous modes with keeping same field flatness & same operating frequency.

 
WEPEC010 Optimization of End Cells of Low Beta Cavity of Higher Energy Part of Project X 2911
 
  • A. Saini
    University of Delhi, Delhi
  • A. Lunin, C.S. Mishra, K. Ranjan, N. Solyak, V.P. Yakovlev
    Fermilab, Batavia
 
 

Eleven cell elliptical cavity is designed for acceleration of particles traveling at 81 % of the speed of light. It will operate at 1.3 GHz and will be used to accelerate the particles from 0.4 GeV to 1.2 GeV. The cavity is studied for higher order mode (HOM) and trapped modes. The shapes of end cells of cavity is optimized to increase the field amplitude in end cells so that coupling of trapped modes may increase with HOM coupler and they can be extracted easily but keeping the field flatness & operating frequency undisturbed.

 
THPD088 Study of Coupler's Effects on ILC Like Lattice 4491
 
  • A. Saini
    University of Delhi, Delhi
  • A. Latina, A. Lunin, K. Ranjan, N. Solyak, V.P. Yakovlev
    Fermilab, Batavia
 
 

It is well known that insertion of a coupler into a RF cavity breaks the rotational symmetry of the cavity, resulting in an asymmetric field. This asymmetric field results in a transverse RF Kick. This RF kick transversely offsets the bunch from the nominal axis & it depends on the longitudinal position of the particle in the bunch. Also, insertion of coupler generates short range transverse wake field which is independent from the transverse offset of the particle. These effects cause emittance dilution and it is thus important to study their behavior & possible correction mechanisms. These coupler effects, i.e. coupler's RF kick & coupler's wake field are implemented in a beam dynamics program, Lucretia. Simulations are performed for main linac & bunch compressor of International Linear Collider (ILC) like lattices. Results are compared with Placet results & a good agreement has been achieved.