Main Linac (ML)

General

• TreatyPoint Definitions : D*0970685, description: D*0972425
• Cavity parameters (draft, not yet released): D*0973245 (Excel)
• Cryomodule parameters (23.2.2012): D*0973345 (Excel)
• Cryogenics parameters for KCS, including ML length (25.6.2012): D*0975575 (Excel)
• Cryogenics parameters for DKS, including ML length (26.6.2012): D*0991555 (Excel)
• Lattice (ML2012a, 2.3.2012) for CFS: D*0977355
• Visualization (JT file): D*0977415

• Summary of decisions from Main Linac and SCRF Baseline Technical Review: D*0977465

• Type 4 Cryomodule (T4CM) CAD model: D*0990821

• KCS Distribution Schematic: D*0970385
• KCS CFS Design Criteria:  D*0970355
• KCS / RDR CFS Cryo Info:   D*0970445

•  DRFS CFS Design Criteria:  D*0970415

Main Linac CFS Criteria

•  Cryo Design Criteria for CFS, 13.8.2012, :   D*0970445

Klystron Cluster Scheme (KCS)

• KCS CFS Design Criteria (final TDR draft Dec 4, 2012):  D*0970355
• Process water plants (KCS, draft Aug 13, 2012):  D*0971245
• KCS Power Load Distribution by Shaft (draft Aug 13, 2012):   D*0974885

• DRFS CFS Design Criteria (draft Aug 16, 2011):  D*0970415
• Process water plants (DRFS, draft Aug 18, 2011):  D*0971215
• DRFS Power KW Load Distribution by Shaft (draft Aug 18, 2011):  D*0971605

Main Linac integration

• TreatyPoint Definitions : D*0970685, description: D*0972425
• Lattice (ML2012a, 2.3.2012) for CFS: D*0977355
• Visualization (JT file): D*0977415

Main Linac Lattice and Beam Dynamics

RDR References

• 94: N. Walker, "Emittance preservation in a possible ILC main linac which follows the earth's curvature,"
  EUROTEV-REPORT-2005-017 (2005).
• 95: P. Eliasson, A. Latina, D. Schulte, F. Poirier and N. Walker, "Study of an ILC main linac that follows the earth curvature,"
  CERN-AB-2006-063, EUROTEV-REPORT-2006-050 (2006). In the Proceedings of 10th European Particle Accelerator Conference (EPAC 06), Edinburgh, Scotland, 26-30 Jun 2006, pp 786-788 (MOPLS096).
• 96: Kirti Ranjan, "Emittance preservation for the curved ILC main linac,"
  Proceedings of LINAC 2006, Knoxville, TN, pp. 192-194 (MOP064).
• 97: A. Latina, I. V. Gonin, K. Ranjan, N. Solyak and V. P. Yakovlev [Linear Collider Collaboration],  "Emittance Dilution Caused by the Couplers in the Main Linac and in the Bunch Compressors of ILC,"
  FERMILAB-CONF-09-158-APC (2009).
  Presented at Particle Accelerator Conference (PAC 09), Vancouver, BC, Canada, 4-8 May 2009, (FR5RFP059).
• 98: J. C. Smith et al. [ILC Beam Physics Group], "Benchmarking / Crosschecking DFS in the ILC Main Linac,''
  FERMILAB-TM-2373-CD, SLAC-TN-06-035 (2007).
  OSTI: 897464
• 99: J. C. Smith, "The preservation of emittance and polarization in the International Linear Collider,''
  Ph.D. Thesis Cornell University (2007),
  UMI Microform 3260825.
• 100:  Kiyoshi Kubo, "Simulation of DFS (Dispersion Free Steering) using SLEPT,''
  ILC-Asia-2006-04 (2006).
• 101: P. Eliasson and D. Schulte, "Dispersion free steering and emittance tuning bumps in the ILC,''
  EUROTEV-REPORT-2005-021 (2005).
• 102.1: Kiyoshi Kubo, "Alignment Tolerances from Single-bunch Effect,''
  ILC-Asia-2005-18 (2005).
• 102.2: Kiyoshi Kubo, "Tolerances of Misalignment of Quads and Cavities of ILC Main Linacs ,''
  ILC-Asia-2005-17 (2005).
• 103: R. M. Jones, R. M. Jones and R. H. Miller, "Mitigation of emittance dilution due to transverse mode coupling in the L-band linacs of the ILC,''
  SLAC-PUB-12469 (2006).
  In the Proceedings of 10th European Particle Accelerator Conference (EPAC 06), Edinburgh, Scotland, 26-30 Jun 2006, pp 843-845 (MOPLS120).
  OSTI: 902486

Further References:

• F. Toral et al., "Magnetization Effects on the Superconducting Combined Magnet Prototype for XFEL,''
  IEEE Trans. Appl. Supercond. 19 (2009) 1136-1140. 
  DOI: 10.1109/TASC.2009.2017706