Design of Transfer Line-2 (TL-2) for CLIC Test Facility – 3 (CTF-3) Amalendu Sharma, A.Rahim, A.D.Ghodke and Gurnam Singh IOAPDD Raja Ramanna Centre for Advanced Technology Indore – India CTF-3 collaboration meeting, January 2007, CERN.
Design of TL-2 for CTF-3, RRCAT, India. Indian participation CTF-3 and Indian participation
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Progress so far First communication for design requirementJuly 15, 2005 Design information received from CERNJuly 22, 2005 Clarification of building geometry and parametersSeptember 22, 2005 First design draft (version-1) communicatedOctober 07, 2005 Comments on first design receivedNovember 10, 2005 Revised design (version-2) communicatedMarch 17, 2006 Comments on revised design receivedApril 17, 2006 Meeting with CERN team in RRCATJune 13-14, 2006 Final specifications receivedJuly 14, 2006 Design draft (version-3) communicatedSeptember 21, 2006 Feedback on implementation of line in buildingNovember 28, 2006 Revised design (version-4) communicatedDecember 20, 2006
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Main requirements of design R 56 from -0.35m to +0.35m. T 566 = 0 in entire range of tuning. = 4-5m and = 0 at exit in both planes. Emittance dilution < 10%. 4m dispersion free region for the tail clippers (collimators). Available magnets to be used. Line implementation in the existing building.
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Output Nominal energy150 MeV Maximum energy300 MeV x, y (m) 8.1, x, y 0.12, , 0.0 0.0 ’’ dp/p (%)1% z (rms) 8.3 ps1.3 ps Height above ground1.35 m0.85 m Beam parameters
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Magnets available Dipole – Type-1 Dipole – Type-2 Stnd. Quadrup ole Slim Quadrup ole TSL Quadrup ole Sextupole Mech. length (m) Mech. width (m) Effective length (m) Aperture (mm) 100 Strength1.3 T 5.4 T/m8 T/m10.6 T/m44 T/m 2 Number
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Geometrical constraints Length of final matching doublet 6.37m 17 4m M 1.21m 3.2m Minimum distance from the edge of element to wall > 50mm
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Design approach Module-1 From extraction point of CR to first bend magnet. An achromat Module-2 Straight section for collimator. vertical achromat, matching section for Module-3 Module-3 Tunable R 56 achromatic arc, Final matching doublet Beam direction. The design studies are carried out using MAD-8 program.
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Design details: Module-1 Module-1 is an achromat with opposite bends from extraction septa of CR to first bend. Very low flexibility in achromat. Quadrupoles close to its highest strength. High at exit of module-1 => Rapid rise in . A Beam direction
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Design details: Module-2 Beam direction Vertical Achromat Space for tail clipper
Design details: Module-3 Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. The linear matrix element for controlling the bunch length Change in Path Length Momentum deviation = p/p Second order relation between path length and momentum deviation
Design details: Module-3 Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Bunch length manipulation (linear) Where chirp Energy-time correlation with RF-field
Design details: Module-3 Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Bunch length manipulation (including second order terms)
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Layout of Module-3 Mirror plane of R 56 arc Beam Direction
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Approach Find out dispersion and its derivative for required R 56 and to form an achromat. Find a solution, such that 1. High sextupoles to control T Decoupled sextupole locations. 3. I – transformer between sextupoles. Required Twiss parameters at Matching point
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Twiss parameters and Dispersion R 56 = (MAD sign convention)
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Twiss parameters and Dispersion Continued… R 56 = 0.00
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Twiss parameters and Dispersion Continued… R 56 = +0.35
Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Vertical dispersion
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. T 566 correction and phase space distortion T 566 Correction with sextupolesPhase space distortion X-PlaneY-Plane R 56 = -0.35m R 56 = 0.00
Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Available Magnets and Power Supplies Needed Dipole magnets Module-1Module-2Module-3 Magnets1 [type-2] 2 [sector type for vertical bend] 4 [2 of type-1 and 2 of type-2] Power supplies112 Quadrupole magnets Module-1Module-2Module-3 Magnets3 [2 slim and 1 TSL] 11 [8 standard and 3 TSL] 12 [TSL-type] Power supplies3107
Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Sextupole magnets Module-1Module-2Module-3 Magnets Power supplies Available Magnets and Power Supplies Needed…
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. A Better Alternative R 56 = For lowering -functions in module-2, one more quadrupole is added in the module-1. Preliminary results are… R 56 = 0.00
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. R 56 = -0.35
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India. Complete layout of line with building
Summary Design of TL-2 for CTF-3, RRCAT, India. CTF-3 collaboration meeting, January 2007, CERN. Optics design in linear zone done for the R 56 from m to +0.35m. T 566 correction studies in progress and preliminary results of R 56 = 0.00 and obtained. -functions higher in module-2 beginning and can be lowered with one more quadrupole in Module-1. Acknowledgements We are thankful to Dr. Hans Braun, Dr. Frank Tecker for the valuable review and feedback during this work.
CTF-3 collaboration meeting, January 2007, CERN. Design of TL-2 for CTF-3, RRCAT, India.