3 Suggested ILC Beam Parameter In choosing gradient, current, followings are assumed MW klystron. 15% overhead for feedback, 6% for WG loss. 2. Cryomodule with 8, 10 or 12 cavities. 3. Bunch spacing : sub-harmonic of 1.3GHz. 4. Keep injector unchanged for 1TeV upgrade, for average current, emittances. In choosing gradient, current, followings are assumed MW klystron. 15% overhead for feedback, 6% for WG loss. 2. Cryomodule with 8, 10 or 12 cavities. 3. Bunch spacing : sub-harmonic of 1.3GHz. 4. Keep injector unchanged for 1TeV upgrade, for average current, emittances. Tor Raubenheimer
Progress and Plans for R&D and the Conceptual Design of the
ILC Main Linacs H. Hayano, KEK PAC2005 5/18/2005 2 Discussions 1.
ILC Main Linac configuration. gradient possible RF unit 2. Test
Facilities for Main Linac RF unit. TTF at DESY SMTF at FNAL STF at
KEK 1. ILC Main Linac configuration. gradient possible RF unit 2.
Test Facilities for Main Linac RF unit. TTF at DESY SMTF at FNAL
STF at KEK 3 Suggested ILC Beam Parameter In choosing gradient,
current, followings are assumed MW klystron. 15% overhead for
feedback, 6% for WG loss. 2. Cryomodule with 8, 10 or 12 cavities.
3. Bunch spacing : sub-harmonic of 1.3GHz. 4. Keep injector
unchanged for 1TeV upgrade, for average current, emittances. In
choosing gradient, current, followings are assumed MW klystron. 15%
overhead for feedback, 6% for WG loss. 2. Cryomodule with 8, 10 or
12 cavities. 3. Bunch spacing : sub-harmonic of 1.3GHz. 4. Keep
injector unchanged for 1TeV upgrade, for average current,
emittances. Tor Raubenheimer 4 Possible example of gradient 1.
40MV/m, 16 cavities(8+8), 11.8mA, 352 buckets spacing MV/m, 20
cavities(10+10), 10.4mA, 384 buckets spacing MV/m, 24
cavities(12+12, 8+8+8), 10.8mA, 400 buckets spacing MV/m, 16
cavities(8+8), 11.8mA, 352 buckets spacing MV/m, 20
cavities(10+10), 10.4mA, 384 buckets spacing MV/m, 24
cavities(12+12, 8+8+8), 10.8mA, 400 buckets spacing. 5 Main Linac
Unit. 1. Choice of nominal gradient. based on TTF experience, total
project cost, Linac length. --> 35MV/m (use of EP) 1. Choice of
nominal gradient. based on TTF experience, total project cost,
Linac length. --> 35MV/m (use of EP) * ~ 1.5 coupling for more
bandwidth. 6 Main Linac Unit. Cont. 2. Choice of optics. based on
Kubos simulation --> Q-magnet in every two modules up to 125GeV
(weak focus) 2. Choice of optics. based on Kubos simulation -->
Q-magnet in every two modules up to 125GeV (weak focus) 3. Choice
of BPM. 1m resolution, 20m misalignment to Q. --> use of 1.5GHz
cavity BPM attached to Q-magnet Quad misalign 300m Q-BPM offset 20m
Quad misalign 300m Cavity misalign 300m Q-BPM offset 20m 7 Proposed
Main Linac Parameters Total number of production Cavity Cryomodule
1424 Klystron 712 Modulator 712 Proposed Main Linac RF unit (low
energy part) Proposed Main Linac RF unit (low energy part) Baseline
technology of RF unit Alternative technology of RF unit 10MW
Multi-beam klystron, 1:12 Pulse trans, HV cable, Bouncer Modulator,
Linear distribution WG, Circulator for each input, TTF style
cryomodule (but 10 cavities), TESLA style 9-cell cavity, Digital
control LLRF, . PPM-MB klystron, Sheet-beam klystron, IGBT
Modulator, No circulator WG, Super-structure cavity, LL-type 9-cell
cavity, Seamless cavity, . ILC Test Facilities in each Region TTF:
leading facility & XFEL production basis. SMTF: US
SC-technology integration. STF: KEK SC-technology integration. TTF:
leading facility & XFEL production basis. SMTF: US
SC-technology integration. STF: KEK SC-technology integration.
Purpose & Role To have an ability of SC-RF technology
Integration into ILC cryomodule & RF unit, To promote regional
industry and laboratories, For production share by three region.
TTF -- TESLA Test Facility TESLA like beam by RF gun. Average
25MV/m. 5 accelerating module(2004) + 35MV/m #6 module(2006) 50m by
bunch compressor ACC 2 & ACC 3 ACC 4 & ACC 5 TTF Linac TTF
TTF2 VUV-FEL accelerator TTF2 commissioning Aug Saturation nmJuly
2005 Operation with full beam current Dec rd Harmonic RF & ACC6
installFeb GeV beam energyApril 2006 Saturation 6 nmJune 2006 TTF2
commissioning Aug Saturation nmJuly 2005 Operation with full beam
current Dec rd Harmonic RF & ACC6 installFeb GeV beam
energyApril 2006 Saturation 6 nmJune nm SASE FEL February, 2005 TTF
for LC & Euro-XFEL TTF2 tunnel for realization of TESLA-LC
European XFEL 20 GeV Main Linac 1.5 km length 29 klystrons 116
cryomodules 928 cavities Cryomodule Test Plan for Euro-XFEL Test
Hall 2009 ~ Cryo-Module Test Bench : 2005 ~ Fabrication by industry
Assemble & Test at DESY SMTF -- Superconducting Module &
Test Facility Assembly Facility Beam Test Area FNAL Meson Area SMTF
-- Superconducting & Module Test Facility 1 cryomodule 2
cryomodules 4 cryomodules Cavity: by Industry Process, Dressed, and
Tested: by collab. Lab./Univ. /Industry Assemble & Test at SMTF
STF -- Superconducting RF Test Facility ATF STF Phase 1: 1
connected module (4 cavities + 4 cavities) Phase 2: 1 ILC RF unit (
2 modules, 20 cavities) Maximum use of existing infrastructure
J-PARC test facility --> STF STF Phase 1 cryomodule : 5m + 5m
connected. Beam test setup of STF Phase 1 Cryomodule cut view
Cryostat cross-section 4 TESLA-type cavities 4 LL-type cavities
Milestone of STF Phase 1 & 2 Phase 1: cool-down Oct beam on Dec
Phase 2: cool-down July 2008 beam on Oct. 2008 Modules in Test
Facilities TTF: total 7 modules, 8 cavities each. [XFEL : 116
modules, 8 cavities each(plan) ] SMTF: total 4 modules, 8 cavities
each(plan). STF: total 3 modules, 8 cavities each for phase 1, 10
cavities each for phase 2(plan). TTF: total 7 modules, 8 cavities
each. [XFEL : 116 modules, 8 cavities each(plan) ] SMTF: total 4
modules, 8 cavities each(plan). STF: total 3 modules, 8 cavities
each for phase 1, 10 cavities each for phase 2(plan). Long-term
Visions of ILC and Test Facilities end The figures and pictures are
borrowed from the following web-site: DESY, FNAL, workshop
presentations and conference papers. I would like to appreciate to
all of presenter. Success of ILC!
