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HEHIHB EU network. W. Scandale CERN Accelerator Technology Department (Thanks to L. Rossi and F. Ruggiero) 23 February 2004. HEHIHB The structure. High Energy High Intensity Hadron Beams (HEHIHB): F.Ruggiero (replacing H.Haseroth)(CERN) /W.Scandale (CERN)
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HEHIHBEU network W. Scandale CERN Accelerator Technology Department (Thanks to L. Rossi and F. Ruggiero) 23 February 2004
HEHIHBThe structure High Energy High Intensity Hadron Beams (HEHIHB): F.Ruggiero (replacing H.Haseroth)(CERN) /W.Scandale (CERN) NA1: Advancements in Accelerator Magnet Technologies (AMT): L.Rossi (CERN) / L.Bottura (CERN) NA2: Novel Methods for Accelerator Beam Instrumentation (ABI): H.Schmickler (CERN) /K.Wittenburg (DESY) NA3: Accelerator Physics and Synchrotron Design (APD): F.Ruggiero / F.Zimmermann (CERN) Walter Scandale - 23 February 2004 - Collège de France - Paris
HEHIHBThe scope • Roadmap towards future Hadron Accelerators • Colliders with energy above 14 TeV • Colliders with luminosity above 2.6 1034 cm-2 s-1 • R&D for future hadron accelerators • Experiments in existing hadron accelerators • Select technologies providing viable options • Prepare the infrastructure for future collaborations • Integrate the effort of major laboratories • Integrate the effort of small labs and universities • Disseminate information • Create an information network • Discuss improvements for existing hadron colliders in Europe Walter Scandale - 23 February 2004 - Collège de France - Paris
HEHIHBThe budget CERN is also responsible for the contacts with the following associated institutes: CRPP, ENEA, TUBE, ESRF, UPSA, LBNL, BNL, FNAL, JINR, IHEP, KEK Walter Scandale - 23 February 2004 - Collège de France - Paris
Kick-off meeting • December 9th, 2003, at CERN (1/2 day) • presentation of the latest status of the proposed AMT activities to the contributing laboratories (scope, time schedule, budget) • contribution of laboratories/universities in terms of study and experimental activity. review of the general capabilities (test facilities) • preparation of the first workshop on superconductors for high-field, high-intensity hadron beams • finalize the plan for the first 18 months of activity of the network • Web-site: http://amt.web.cern.ch/amt/ Walter Scandale - 23 February 2004 - Collège de France - Paris
Other events of HEHIHC Walter Scandale - 23 February 2004 - Collège de France - Paris
Requests to CERN Walter Scandale - 23 February 2004 - Collège de France - Paris
Publications in preparation Walter Scandale - 23 February 2004 - Collège de France - Paris
HEHIHB - WP1Accelerator Magnet Technology Networking activity
LHC: What might be next? Radiation damage limit ~700 fb-1 • Due to the high radiation doses to which they will be submitted, the life expectancy of LHC IR quadrupole magnets is estimated ~5-7 years. • Hence, it is likely that these magnets will have to be replaced in 2013-2015, thereby offering an opportunity of upgrading LHC IR optics to improve luminosity. Courtesy of F. Ruggiero and Jim Strait • Mid-2010’s is also the earliest time frame when one can expect to need final-focusing quadrupole magnets for any of the proposed projects of linear colliders. At least one needs very strong wide final triplets. Walter Scandale - 23 February 2004 - Collège de France - Paris
State of the Art in NbTi • Since the Tevatron, the most widely used superconductor is NbTi (world production: ~1500 t/year). • The LHC magnet R&D programs have shown that the limit of NbTi at 1.8 K was around 10 to 10.5 T. • Hence, to go beyond the 10-T threshold, it is necessary to change the material. Quench performance of 88-mm-aperture MFRESCA dipole magnet at CERN built by D. Leroy team. Walter Scandale - 23 February 2004 - Collège de France - Paris
Beyond NbTi • High Temperature Superconductors (HTS)are not yet ready for large-scale applications requiring high current densities under high magnetic fields, and it is likely that it will take at least another decade before they become competitive (in terms of performances, yield and cost). • The upper critical field of MgB2is too low. • Nb3Alexhibits promising properties but there are serious manufacturing issues that have yet to be resolved. • At present, the only serious candidate to succeed NbTi, suitable for industrial production in the next 5 years, is the intermetallic compoundNb3Sn (world production amounts to ~15 t/year). Walter Scandale - 23 February 2004 - Collège de France - Paris
The path for High-Field Accelerator Magnet R&D • A reasonable roadmap for high-field accelerator magnet development appears to be • get ready for LHC-IR upgrade in 2013-15 • (large-aperture, high-performance dipole and/or quadrupole magnets; cost is not the primary issue), • The real R&D -focussed- is here, and it will be the base for all the other possible goals • develop final-focusing quadrupole magnets for implementation in alinear collider IR in the mid-2010’s • (LHC-type quadrupole magnets in a solenoidal background field, or compact quadrupole magnets; cost is not the primary issue), • Some magnet R&D aimed at LHC energy upgrade or a VLHC in the 2020’s (high-performance, low-cost dipole). Walter Scandale - 23 February 2004 - Collège de France - Paris
What do we have to do in the frame of HEHIHC? • Review if really we need this change in technology or if different IR schemes can do the job by using improved NbTi or NbTiTa (1T beyond NbTi) • Meanwhile: • revisit magnetic and mechanical designs to achieve enhanced performances with coils made from brittle conductors, • address coil cooling issue under high beam losses, • keep promoting high-performance Nb3Sn wire development (ensuring the survival of multiple suppliers around the world), • improve mechanical robustness and assess radiation hardness of Nb3Sn conductor insulation, • put into practice all of the above in magnet models and prototypes. Walter Scandale - 23 February 2004 - Collège de France - Paris
11 contributing associations: CEA (Saclay, France) CERN (Geneva, Switzerland) CIEMAT (Madrid, Spain) EPFL/CRPP (Villigen, Switzerland) GSI (Darmstadt, Germany) ENEA (Frascati, Italy) FZK (Karlsruhe, Germany) INFN-GE (Genova, Italy) INFN-MI (Milano, Italy) RAL (Chilton, UK) UT (Enschede, The Netherlands) WUT (Wroclaw, Poland) 5 associated international laboratories: LBNL (Berkeley, CA, USA) FNAL (Chicago, IL,USA) BNL (Upton, NY, USA) JINR (Dubna, Russia) KEK (Tsukuba, Japan) Contributors to WP1 Walter Scandale - 23 February 2004 - Collège de France - Paris
Scope of the WP1 • 5 critical study and R&D tasks identified based on present state-of-the-art in magnet and accelerator technology : • AMT-1 - Stability and Quench Limit of LHC at Ultimate Field and for LHC Upgrades (L+E) • AMT-2 - Pulsed Magnets (for an SPS Upgrade) (L) • AMT-3 - Magnets for a LE Ring in the LHC Tunnel (L) • AMT-4 - High Field Magnet Design (L+E) • AMT-5 - Optimisation of the overall Cost of the Magnet System for a High Energy-High Intensity Hadron Collider • Task on synchrotron radiation handling dropped Walter Scandale - 23 February 2004 - Collège de France - Paris
contributing labs/universities associated labs/universities The World after AMT Walter Scandale - 23 February 2004 - Collège de France - Paris
Work Matrix Contributing Labs Walter Scandale - 23 February 2004 - Collège de France - Paris
Work Matrix: Associated Labs Walter Scandale - 23 February 2004 - Collège de France - Paris
Budget cost funding obtained Walter Scandale - 23 February 2004 - Collège de France - Paris
Budget - profile • topics by year: • HF SC materials • HF magnet design • HF and LF magnet design • collider issues • S-LHC options Walter Scandale - 23 February 2004 - Collège de France - Paris
This money and energy for what ? - I: IR • L=3-4 1034 ? Explore the route of NbTiTa and improved NbTi !! • Large X-ing angles (4 mrad!!) separated beam quads!! • However first quadrupole really difficult!! • To see if the 14 T -9 m dipole can be made 10 T -14 m (the scope is to avoid Nb3Sn technology) • Evaluate (ABP) if the difficulties are not simply transposed (superbunches) • Can somebody invest in a 2-3 year development in NbTiTa? First proposed by J. Strait and co. Walter Scandale - 23 February 2004 - Collège de France - Paris
This money and energy for what ? - II: IR Very first NED coil lay-out for 15 T.O. Vincent Viry • To prepare technology for the “more classical” scheme. Here very large quads are needed; high field dipoles are needed as well. A. Zlobin, FNAL Walter Scandale - 23 February 2004 - Collège de France - Paris
This money and energy for what ? - III: IR N. V. Mokhov et al. , Fermilab Walter Scandale - 23 February 2004 - Collège de France - Paris
This money and energy for what ? - IV: stability issue • Review the stability limit of our Sc magnets. • With the experience gained so far, the assessment of the achievable cleaning, the actual limit should be re-evaluated • Is there a hard limit for going beyond ultimate ? Walter Scandale - 23 February 2004 - Collège de France - Paris
This money and energy for what ? - V: INJ from a SSPS • Collaboration GSI-CERN already existing; GSI is active part of the network • The high energy ring need pulsed, 1T/s ramp, 6 T magnets (4T till 1 year ago) • BNL has been very successful to built a working 4T - 2T/s dipole with special insulation as suggested by M.N. Wilson Walter Scandale - 23 February 2004 - Collège de France - Paris
Activity start-up - general • for the next 18 months the main focus is on: • superconducting materials for high-field accelerator magnets • mainly Nb3Sn… • … and NbTiTa, • Nb3Al, • High-Tc materials (BSSCO, YBCO), • and MgB2 • R&D and design activities in support of the NED development (accelerator-quality 15 T dipole magnet) • Starting EU data base of Sc and Sc magnets Walter Scandale - 23 February 2004 - Collège de France - Paris
Activity start-up - Q1 2004 • Workshop on Superconductors for High-Field, High-Intensity Hadron Beams • 3 days workshop • organised by CERN (Archamps ) • to take place 22-24 March 2004 • attendance by invitation • ALL European firms for both LTc and HTc superconducting materials • leading European laboratories and universities • representatives from US (LARP program) and Japan • About 60 people in total Walter Scandale - 23 February 2004 - Collège de France - Paris
Activity start-up - Q1 2004 • Aim of the workshop: • Review the status of the world R&D on superconducting materials and cables for high field magnets (B > 10 T), with particular focus on needs on the NED program (Nb3Sn) • Review the capabilities of European industries and European laboratories in support of the superconductor R&D • Identify needs and define directions of development for industry and laboratories Walter Scandale - 23 February 2004 - Collège de France - Paris
HEHIHB - WP4Accelerator Physics and Synchrotron Design Networking activity
Scope of the WP4 • Collaboration on fundamental Accelerator Physics and Optics Design • optics design criteria for booster synchrotrons • intensity limitations arising from conventional impedance, beam-beam or electron cloud effects. • linear and nonlinear optics modelling, including space charge and machine imperfections, • development of simulation codes to study halo formation and electron cloud effects. • Comparisons and benchmarking of the codes by beam measurements • In collaboration with ABI, establish a parallel working infrastructure in Europe to the proposed US-LARP programme, to streamline R&D work in the 3 big national labs in the US with the additional benefit of contributing to LHC upgrade studies. • A parallel US-LARP and CARE approach would facilitate the information flow and the worldwide collaboration efforts. Walter Scandale - 23 February 2004 - Collège de France - Paris
New Interaction Regions for LHC Luminosity Upgrade: beam dynamics vs magnet technology and design Walter Scandale - 23 February 2004 - Collège de France - Paris
Delivrables of the WP4 (1/3) • Form a working group to review, prioritise, and coordinate beam dynamics studies immediate scopes: • better modelling and understanding of electron cloud effects and their remedies having direct implications for vacuum chamber design, beam instrumentation, and machine performance • beam optics constraints, machine protection, and long term stability • design criteria for Interaction Region layout and magnetic field quality. Walter Scandale - 23 February 2004 - Collège de France - Paris
Delivrables of the WP4 (2/3) • Provide a common repository for linear and nonlinear optics programs, impedance estimates, and simulation codesfor collective effects (conventional instabilities, beam-beam, space charge, and electron cloud effects). • Coordinate the validation of these codes by mutual comparisons and benchmarking by machine experiments, and provide centralised documentation. • Coordinate extension of the simulation codes to cover the relevant beam physics and the implementation of effective procedures for beam measurements, machine protection, background control, and performance optimisation. Walter Scandale - 23 February 2004 - Collège de France - Paris
Delivrables of the WP4 (3/3) • Organize regular workshops and collaboration meetings. Publish workshop proceedings in electronic form, with the system of the peer review. The last workshop and the last annual report will provide general conclusions, design options, and guidelines concerning intensity limitation mechanisms and strategies to achieve high energy/high intensity hadron beams in existing or future facilities. • Publish annual reports indicating the progress of the integration activity among various institutes and addressing each single work-package and a global assessment of the progress toward HE-HI hadron beams. Walter Scandale - 23 February 2004 - Collège de France - Paris
Planning of the WP4 Walter Scandale - 23 February 2004 - Collège de France - Paris
Conclusion • The EU CARE HEHIHB program offers a coherent frame to carry out studies for the next generation of high-field/low field accelerator stemming on LHC-IR upgrade • Studies and evaluations of accelerator physics issues will be addressed andresources from other labs will be solicited and oriented • On going activity on beam instrumentation will be strengthened and focused to develop novel instruments for a more efficient running in and operation of hadron accelerators Walter Scandale - 23 February 2004 - Collège de France - Paris