Download presentation
Presentation is loading. Please wait.
1
Barry Barish Paris ICHEP 24-July-10
ILC Global Design Effort Barry Barish Paris ICHEP 24-July-10 24-July ICHEP-10 Paris Global Design Effort
2
Linear Collider – Higgs Physics
Measure the quantum numbers. The Higgs must have spin zero ! The linear collider will measure the spin of any Higgs it can produce by measuring the energy dependence from threshold 24-July ICHEP-10 Paris Global Design Effort
3
Precision measurements of Higgs coupling
Linear Collider – Higgs Physics Precision measurements of Higgs coupling Higgs Coupling strength is proportional to Mass 24-July ICHEP-10 Paris Global Design Effort
4
determine the underlying model
Linear Collider – Higgs Physics determine the underlying model SM 2HDM/MSSM Zivkovic et al Yamashita et al 24-July ICHEP-10 Paris Global Design Effort
5
RDR Complete Reference Design Report (4 volumes) Physics Executive
Summary Physics at the ILC Detectors Accelerator 24-July ICHEP-10 Paris Global Design Effort
6
RDR Design Parameters Max. Center-of-mass energy 500 GeV
Peak Luminosity ~2x1034 1/cm2s Beam Current 9.0 mA Repetition rate 5 Hz Average accelerating gradient 31.5 MV/m Beam pulse length 0.95 ms Total Site Length 31 km Total AC Power Consumption ~230 MW 24-July ICHEP-10 Paris Global Design Effort
7
Major R&D Goals for Technical Design
Accelerator Design and Integration (AD&I) Studies of possible cost reduction designs and strategies for consideration in a re-baseline in 2010 SCRF High Gradient R&D - globally coordinated program to demonstrate gradient by 2010 with 50%yield; ATF-2 at KEK Demonstrate Fast Kicker performance and Final Focus Design Electron Cloud Mitigation – (CesrTA) Electron Cloud tests at Cornell to establish mitigation and verify one damping ring is sufficient. 24-July ICHEP-10 Paris Global Design Effort Global Design Effort 7 7
8
Why change from RDR design?
Timescale of ILC demands we continually update the technologies and evolve the design to be prepared to build the most forward looking machine at the time of construction. Our next big milestone – the technical design (TDR) at end of 2012 should be as much as possible a “construction project ready” design with crucial R&D demonstrations complete and design optimised for performance to cost to risk. Cost containment vs RDR costs is a crucial element. (Must identify costs savings that will compensate cost growth) 24-July ICHEP-10 Paris Global Design Effort
9
Project Implementation Plan
Five Themes to Develop Remains special case Project Implementation Plan Industrialisation in-kind contribution models Site requirements Project Schedule Remaining Technical activities Regional expertise, global Industrialisation Average accelerating gradient Cost (cryomodule, mass-production models) SCRF Technology Sources DR (e-cloud) BDS / MDI R&D (General) Consolidation of baseline(s) Design choices (parameters, layout etc.) Design work (documentation) AD&I (CFS) ICET (schedule tool) Traceable, defendable Justification Cost & Schedule R&D (and engineering) beyond 2012 Impact (design, cost, schedule) Mitigation (fall-back solutions) TDR Risk >2012 24-July ICHEP-10 Paris Global Design Effort Global Design Effort 9 9 9
10
Technical Design Phase and Beyond
change control process AAP PAC Physics TDP Baseline Technical Design TDR RDR Baseline SB2009 evolve TDP-2 TDP-1 Beijing Workshop CERN Workshop Change Request RDR Alternate concepts R&D Demonstrations AD&I studies 2009 2010 2011 2012 2013 24-July ICHEP-10 Paris Global Design Effort 10
11
Proposed Design changes for TDR
RDR SB2009 Single Tunnel for main linac Move positron source to end of linac *** Reduce number of bunches factor of two (lower power) ** Reduce size of damping rings (3.2km) Integrate central region Single stage bunch compressor 24-July ICHEP-10 Paris Global Design Effort
12
7.5 m Diameter Single Tunnel
Egress passageway not needed; 7 m Ø ok 24-July ICHEP-10 Paris Global Design Effort 12 12
13
7.5 m Diameter Single Tunnel High-Level RF Solution
Critical technical challenge for one-tunnel option is the high level RF distribution. Two proposed solutions : Distributed RF Source (DRFS) Small 750kW klystrons/modulators in tunnel One klystron per four cavities ~1880 klystrons per linac Challenge is cost and reliability Klystron Cluster Scheme (KCS) RDR-like 10 MW Klystrons/modulators on surface Surface building & shafts every ~2 km Challenge is novel high-powered RF components (needs R&D) 24-July ICHEP-10 Paris Global Design Effort
14
The ILC SCRF Cavity Achieve high gradient (35MV/m); develop multiple
vendors; make cost effective, etc Focus is on high gradient; production yields; cryogenic losses; radiation; system performance 24-July ICHEP-10 Paris Global Design Effort
15
24-July ICHEP-10 Paris Global Design Effort
16
24-July ICHEP-10 Paris Global Design Effort
17
24-July ICHEP-10 Paris Global Design Effort
18
24-July ICHEP-10 Paris Global Design Effort
19
Cornell E Cloud Studies
24-July ICHEP-10 Paris Global Design Effort
20
24-July ICHEP-10 Paris Global Design Effort
21
Interaction Region Break point for push-pull disconnect Provide reliable collisions of 5nm-small beams, with acceptable level of background, and be able to rapidly and efficiently exchange ~10kT detectors in a push-pull operation several times per year (old location) 24-July ICHEP-10 Paris Global Design Effort 21
22
Push – Pull Detector Concept
Both detectors without platforms Both detectors with platforms Vibration stability will be one of the major criteria in eventual selection of a motion system design 24-July ICHEP-10 Paris Global Design Effort 22
23
Timescales: TDR to ILC (or beyond 2012)
Steps to a Project – Technical (2-3 years) R&D for Risk Reduction and Technology Improvement Systems Tests (e.g. S2 completion – ILC-like beam tests) Engineering Design Industrialization Project Implementation Government Agreements for International Partnership Siting and site-dependent design Governance Time to Construct 5-6 years construction 2 years commissioning Project Proposal / Decision keyed to LHC results ILC Could be doing physics by early to mid- 2020s 24-July ICHEP-10 Paris Global Design Effort Global Design Effort 23 23
24
Final Remarks ILC accelerator R&D and design evolution is on track for Technical Design Report at end of This will be accompanied a Project Implementation Plan Planning for ILC development beyond 2012 is very important. It will be very difficult to maintain viable support until a decision will be made. LHC will open the TeV energy frontier and the resulting physics will point our way to the future ---- (Linear Collider or ???). We are preparing to make the ILC option as a viable and well prepared and understood option. 24-July ICHEP-10 Paris Global Design Effort
Similar presentations
© 2024 SlidePlayer.com Inc.
All rights reserved.