1. Linac4 and SPL Linac4 and SPL R. Garoby for the linac team

2. R. G. 2 3 rd IFMIF Workshop – 7 March 2007 Layout of the new injectors SPS PS2 SPL Linac4 PS

3. R. G. 3 3 rd IFMIF Workshop – 7 March 2007 LINAC4 Technical Design Report (December 2006) CERN-AB-2006-084, http://cdsweb.cern.ch/record/1004186 L. Arnaudon, P. Baudrenghien, M. Baylac, G. Bellodi, Y. Body, J. Borburgh, P. Bourquin, J. Broere, O.Brunner, L. Bruno, C. Carli, F. Caspers, S.; Cousineau, Y. Cuvet, C. De Almeida Martins, T. Dobers, T. Fowler, R. Garoby, F. Gerigk, B. Goddard, K. Hanke, M. Hori, M. Jones, K. Kahle, W. Kalbreier, T. Kroyer, D. Küchler, A.M Lombardi, L.A López-Hernandez, M. Magistris, M. Martini, S. Maury, E.Page, M. Paoluzzi, M. Pasini, U. Raich, C. Rossi, J.P Royer, E. Sargsyan, J. Serrano, R. Scrivens, M. Silari, M. Timmins, W.Venturini-Delsolaro, M. Vretenar, R. Wegner, W. Weterings, T. Zickler

4. R. G. 4 3 rd IFMIF Workshop – 7 March 2007 Linac4 parameters 2 operating modes: low duty for PS Booster (PSB) injection in the first phase, high duty for the SPL in a second phase.  Structures and klystrons dimensioned for 50 Hz  Power supplies and electronics dimensioned for 2 Hz. Will re-use 352 MHz LEP RF components: klystrons, waveguides, circulators. Ion speciesH− Output Energy160MeV Bunch Frequency352.2MHz Max. Rep. Rate2 Hz Beam Pulse Length400  s Max. Beam Duty Cycle0.08 % Chopper Beam-on Factor62 % Chopping scheme: 222 transmitted /133 empty buckets Source current80 mA RFQ output current70mA Linac current40mA N. particles per pulse1.0× 10 14 Transverse emittance0.4  mm mrad Max. rep. rate for accelerating structures 50 Hz

5. R. G. 5 3 rd IFMIF Workshop – 7 March 2007 Linac4 topology DTLCCDTLSCL 3MeV40MeV90MeV160MeV Drift Tube Linac 352 MHz 13.4 m 3 tanks 5 klystrons 4 MW 82 PMQuad Side Coupled Linac 704 MHz 28 m 20 tanks 4 klystrons 12 MW 20 EMQuads Cell-Coupled Drift Tube Linac 352 MHz 25.3 m 24 tanks 8 klystrons 6.5 MW 24 EMQuads Duty cycle: 0.1% phase 1 (Linac4) 3-4% phase 2 (SPL) (design: 15%) 4 different structures, (RFQ, DTL, CCDTL, SCL) 2 frequencies Total Linac4: 80 m, 18 klystrons current: 40 mA (avg. in pulse), 65 mA (bunch) CHOPPERRFQ Chopper 352 MHz 3.6 m 11 EMquad 3 rf cavity Radio Frequency Quadrupole (IPHI) 352 MHz 6 m 1 Klystron 1 MW H- 3MeV95keV RF volume source (DESY) 35 kV Extrac. 60kV Postacc.

6. R. G. 6 3 rd IFMIF Workshop – 7 March 2007 The IPHI RFQ The 3 MeV Test Stand, Linac4 and finally SPL will use an RFQ being built using IPHI technology (brazing at CERN). The RFQ is expected at CERN before the end of 2008.

7. R. G. 7 3 rd IFMIF Workshop – 7 March 2007 The 3 MeV chopper line Compact design 3.7 m length Dynamic range 20 – 60 mA Small  growth 4% long., 8% trans. Tolerant to alignment errors Chopper structure: double meander strip line, 400mm length, metallized ceramic plate. 2 ns rise/fall time for bunch selectivity (352 MHz beam structure), ±500V between deflecting plates. Dumping of chopped beam and collimation of unchopped beam in a conical dump structure 3 RF bunchers

8. R. G. 8 3 rd IFMIF Workshop – 7 March 2007 Linac4 accelerating structures

9. R. G. 9 3 rd IFMIF Workshop – 7 March 2007 Cell Coupled DTL Used above 40 MeV: focusing periods can be longer  structure with external quadrupoles, placed between short DTL-like tanks With respect to DTL: can use electro- magnets, easy access and cooling, easier machining and alignment, simpler and more economic construction Modules of 3 tanks connected by coupling cells, 2 drift tubes per tank High-power prototype tested at CERN

10. R. G. 10 3 rd IFMIF Workshop – 7 March 2007 SPL Conceptual Design Report (July 2006) CERN-2006-006, http://cdsweb.cern.ch/record/975366http://cdsweb.cern.ch/record/ Baylac, MBaylac, M; (LPSC Grenoble) Gerigk, F (ed.); Benedico-Mora, E; Caspers, F; Chel, S (CEA Saclay) ; Deconto, J M (LPSC Grenoble) ; Duperrier, R (CEA Saclay) ; Froidefond, E (LPSC Grenoble) ; Garoby, R; Hanke, K; Hill, C; Hori, M (CERN and Tokyo Univ.) ; Inigo-Golfin, J; Kahle, K; Kroyer, T; Küchler, D; Lallement, J B; Lindroos, M; Lombardi, A M; López Hernández, A; Magistris, M; Meinschad, T K; Millich, Antonio; Noah-Messomo, E; Pagani, C (INFN Milan) ; Palladino, V (INFN Naples) ; Paoluzzi, M; Pasini, M; Pierini, P (INFN Milan) ; Rossi, C; Royer, J P; Sanmartí, M; Sargsyan, E; Scrivens, R; Silari, M; Steiner, T; Tückmantel, Joachim; Uriot, D (CEA Saclay) ; Vretenar, M;Gerigk, FBenedico-Mora, ECaspers, FChel, S Deconto, J MDuperrier, RFroidefond, EGaroby, RHanke, KHill, CHori, MInigo-Golfin, JKahle, KKroyer, TKüchler, D Lallement, J BLindroos, MLombardi, A MLópez Hernández, AMagistris, MMeinschad, T KMillich, AntonioNoah-Messomo, EPagani, CPalladino, VPaoluzzi, MPasini, MPierini, PRossi, CRoyer, J PSanmartí, MSargsyan, EScrivens, RSilari, M Steiner, TTückmantel, JoachimUriot, DVretenar, M

11. R. G. 11 3 rd IFMIF Workshop – 7 March 2007 SPL New Layout (CDR2, 2006) LINAC4 New SPL Design (CDR2, CERN Yellow Report 2006-006): Linac4 (extended to 180 MeV) + 2 superconducting sections based on 5-cell elliptical cavities at 704 MHz (INFN/CEA). Long cryomodules (LHC/TESLA-like, 12-14m), 6-8 cav./module, cold quads in cryomodules Overall length 430m (for 3.5 GeV, was 370m in previous version for 2.2 GeV) Medium  High  Cavity  0.651 R/Q (Ohm) 235575 Aperture (mm) 8590 E p /E acc 2.62.4 E acc (MV/m) 1925

12. R. G. 12 3 rd IFMIF Workshop – 7 March 2007 SPL Beam parameters 4 different designs: CDR1 (2000) based on LEP-type SC cavities (352 MHz) CDR2 (2006) based on 700 MHz high-gradient cavities CDR2+ (2006) at higher energy, for the needs of neutrino production SPL for LHC (2007) at low beam power, for the needs of the LHC

13. R. G. 13 3 rd IFMIF Workshop – 7 March 2007 SPL cavities: elliptical, 704 MHz Elliptical cavities at  =0.5 (CEA, INFN) are giving promising results. Stiffened for pulse operation. Length ~ 0.9m Designed for 12 MV/m. * Feed 4 to 6 cavities per klystron: use high power phase and amplitude modulators.

14. R. G. 14 3 rd IFMIF Workshop – 7 March 2007 ROADMAP

15. R. G. 15 3 rd IFMIF Workshop – 7 March 2007 CDR 2 Planning of the new injectors Linac4 approval 3 MeV test place ready SPL & PS2 approval

16. R. G. 16 3 rd IFMIF Workshop – 7 March 2007 INDIA: klystron power supplies, RF structures CHINA: quadrupoles, magnets SAUDI ARABIA: RF prototypes H - source RFQ DTL 95 keV 3 MeV 40 MeV 90 MeV 160 MeV chopper line CCDTL SCL transfer line to PSB LEBT 352 MHz 704 MHz 80 m Network of collaborations for the R&D phase, with the support of the EU-FP6 and ISTC, or in the frame of CERN-CEA/IN2P3 and CERN-India agreements. Present collaborations for R & D on Linac4

17. R. G. 17 3 rd IFMIF Workshop – 7 March 2007  Refinement of the overall proposal (PAF with POFPA) Selection of the most promissing scenarios for the LHC upgrade Optimization of compatibility with other users (EURISOL, neutrinos, pbars, heavy ions…) Creation of study teams Preparation for requests in the FP7  Design optimization High energy accelerating structures / RF frequency Refinement of beam optics Detailed equipment design (e.g. beam instrumentation) Injection and capture in the PSB (transverse & longitudinal)  Analysis of different options for the site Optimum layout for the complete injector complex Ongoing work for Linac4

18. R. G. 18 3 rd IFMIF Workshop – 7 March 2007   April 2007 Final negotiation of detailed work packages with external partners Site selection  Beginning of May 2007 Submission of proposals to governing & financing authorities Submission of CNI for LHC upgrade to the E.U. Beam instrumentation review  End June 2007 Statement of position of governing & financing authorities CERN Council decision on the « White paper »  July  September 2007 Finalization of the design (updated design report) Conclusion on allocation of work packages Distribution of « remaining » tasks inside CERN  September  December 2007 Project review Project organization inside CERN  January 2008: official start of the Linac4 project Linac4 roadmap in 2007