08/11/2007M. Giovannozzi – CARE-HHH-APD IR’071 Optics issues for Phase 1 and Phase 2 upgrades Massimo Giovannozzi, CERN Outline: –Option for Phase 1 and.

Slides:



Advertisements
Similar presentations
Heat load due to e-cloud in the HL-LHC triplets G. Iadarola, G. Rumolo 19th HiLumi WP2 Task Leader Meeting - 18 October 2013 Many thanks to: H.Bartosik,
Advertisements

Study of the Luminosity of LHeC, a Lepton Proton Collider in the LHC Tunnel CERN June F. Willeke, DESY.
Long-range beam-beam compensation at HL-LHC Tatiana Rijoff, Frank Zimmermann ColUSM # /03/2013.
24/01/08Energy deposition, LIUWG, Elena Wildner1 Upgrade phase 1: Energy deposition in the triplet Elena Wildner Francesco Cerutti Marco Mauri.
Two Scenarios for the LHC Luminosity Upgrade Walter Scandale, Frank Zimmermann ACES workshop We acknowledge the support of the European Community-Research.
Summary of Session 1: Optics and Layout P. Raimondi.
Round table magnet discussion and conclusions CARE-HHH IR’07 animated by W. Scandale and F. Zimmermann.
Crab Cavities in IR1 and IR5 Some considerations on tunnel integration What will be the situation in the tunnel after the LHC IR Phase-1 Upgrade. What.
The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.
October 4-5, Electron Lens Beam Physics Overview Yun Luo for RHIC e-lens team October 4-5, 2010 Electron Lens.
CASA Collider Design Review Retreat HERA The Only Lepton-Hadron Collider Ever Been Built Worldwide Yuhong Zhang February 24, 2010.
The Large Hadron Collider Contents: 1. The machine II. The beam III. The interaction regions IV. First LHC beam [R. Alemany] [CERN AB/OP] [Engineer In.
Guido Sterbini CERN – MCS - MA Section Meeting, 8 th February 2007.
Optimization of Field Error Tolerances for Triplet Quadrupoles of the HL-LHC Lattice V3.01 Option 4444 Yuri Nosochkov Y. Cai, M-H. Wang (SLAC) S. Fartoukh,
General Considerations for the Upgrade of the LHC Insertion Magnets
1 BNL LARP Accelerator Physics Program Resources BNL role in national program BNL Accelerator Physics Program.
Global Design Effort ILC Crab Cavity Overview and requirements Andrei Seryi SLAC on behalf of ILC Beam Delivery and Crab-Cavity design teams Joint BNL/US-LARP/CARE-HHH.
Thursday Summary of Working Group I Initial questions I: LHC LUMI 2005; ; ArcidossoOliver Brüning 1.
ERHIC design status V.Ptitsyn for the eRHIC design team.
Flat-beam IR optics José L. Abelleira, PhD candidate EPFL, CERN BE-ABP Supervised by F. Zimmermann, CERN Beams dep. Thanks to: O.Domínguez. S Russenchuck,
Plan for Review of FCC- ee Optics and Beam Dynamics Frank Zimmermann FCC-ee Design Meeting 31 August 2015.
LHC-CC Validity Requirements & Tests LHC Crab Cavity Mini Workshop at CERN; 21. August Remarks on using the LHC as a test bed for R&D equipment.
Beam-beam compensation at RHIC LARP Proposal Tanaji Sen, Wolfram Fischer Thanks to Jean-Pierre Koutchouk, Frank Zimmermann.
F. Willeke, Snowmass Luminosity Limitations of e-p Colliders Extrapolation from HERA Experience Examples for IR Layout LINAC-Ring Limitations HERA.
J.P. Koutchouk, L. Rossi, E. Todesco A phase-one LHC luminosity upgrade based on Nb-Ti J.P. Koutchouk, L. Rossi, E. Todesco Magnets, Cryostats and Superconductors.
Already time to think of upgrading the machine Two options presently discussed/studied Higher luminosity ~10 35 cm -2 s -1 (SLHC) –Needs changes in.
Β*-dependence on collimation R. Bruce, R.W. Assmann C. Alabau Pons, F. Burkart, M. Cauchi, D. Deboy, M. Giovannozzi, W. Herr, L. Lari, G. Muller, S. Redaelli,
1 Task particle simulations studies: progress report M. Giovannozzi Objectives To study the field quality tolerances for new magnetic elements for.
The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.
1 RHIC II – Ion Operation Wolfram Fischer RHIC II Workshop, BNL – Working Group: Equation of State 27 April 2005.
The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.
Francesco Cerutti ENERGY DEPOSITION ASPECTS FOR LHCb REQUEST 5th Joint HiLumi LHC - LARP Annual Meeting Oct 29, 2015 through L.S. Esposito’s work and essential.
Overview of Wire Compensation for the LHC Jean-Pierre Koutchouk CARE-HHH Meeting on beam-beam effects and beam-beam compensation CERN 08/28/2008.
E. Todesco LAYOUT FOR INTERACTION REGIONS IN HI LUMI LHC E. Todesco CERN, Geneva Switzerland Acknowledgements: B. Dalena, M. Giovannozzi, R. De Maria,
E. Todesco, Milano Bicocca January-February 2016 Unit 2 Magnets for circular accelerators: the interaction regions Ezio Todesco European Organization for.
Tentative conclusions. Beam parameters new parameter sets with acceptable electron cloud & pile-up events 25 ns spacing ultimate beam with low  * - may.
Optics with Large Momentum Acceptance for Higgs Factory Yunhai Cai SLAC National Accelerator Laboratory Future Circular Collider Kick-off Meeting, February.
Collimation Aspects for Crab Cavities? R. Assmann, CERN Thanks to Daniel Wollmann for presenting this talk on my behalf (criticism and complaints please.
Expected field quality in LHC magnets E. Todesco AT-MAS With contributions of S. Fartoukh, M. Giovannozzi, A. Lombardi, F. Schmidt (beam dynamics) N. Catalan-Lasheras,
Layout and Arcs lattice design A. Chancé, B. Dalena, J. Payet, CEA R. Alemany, B. Holzer, D. Schulte CERN.
Field Quality Specifications for Triplet Quadrupoles of the LHC Lattice v.3.01 Option 4444 and Collimation Study Yunhai Cai Y. Jiao, Y. Nosochkov, M-H.
The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.
Turnaround time in modern hadron colliders & store-length optimization
Operating IP8 at high luminosity in the HL-LHC era
contribution to the round table discussion
Energy deposition studies on magnets. Aim. First applications
LUMI06 preliminary conclusions
D0 and its integrability
LHeC interaction region
fundamental equations of LHC performance
Field quality update and recent tracking results
Large Booster and Collider Ring
Joint Meeting SPS Upgrade Study Group and SPS Task Force
Follow-up of HL-LHC Annual meeting
Β*-reach in 2017 R. Bruce, S. Redaelli, R. De Maria, M. Giovannozzi, A. Mereghetti, D. Mirarchi Acknowledgement: collimation and optics teams, BE/ABP,
Field quality to achieve the required lifetime goals (single beam)
LHC Accelerator Upgrade
UPDATE ON DYNAMIC APERTURE SIMULATIONS
Upgrade phase 1: Energy deposition in the triplet
Possible Scenarios for an LHC Upgrade
Collimation margins and *
HL-LHC operations with LHCb at high luminosity
Frank Zimmermann & Walter Scandale
Thursday Summary of Working Group I
Negative Momentum Compaction lattice options for PS2
Triplet corrector layout and strength specifications
Negative Momentum Compaction lattice options for PS2
Crab Crossing Named #1 common technical risk (p. 6 of the report)
Fanglei Lin JLEIC R&D Meeting, August 4, 2016
Large emittance scenario for the Phase II Upgrade of the LHC
Presentation transcript:

08/11/2007M. Giovannozzi – CARE-HHH-APD IR’071 Optics issues for Phase 1 and Phase 2 upgrades Massimo Giovannozzi, CERN Outline: –Option for Phase 1 and 2 upgrades. –Development and issues of Phase 1 upgrade studies. –Issues of Phase 2 upgrade studies. –Conclusions and outlook. Acknowledgements: AB and AT colleagues contributing to the upgrade studies

LHC IR Upgrade options - I Phase 1: consolidation of ‘ultimate’ performance with L > cm -2 s -1 –Large aperture NbTi triplet magnets using existing spare dipole cables. –The goal is also of introducing additional margins for the LHC operation. –No modifications of the experiment interface and cryogenic infrastructure. –Opening the option for operation with  * = 0.25 m and the LHC ‘ultimate’ beam. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’072

LHC IR Upgrade options - II Phase 2: ambitious upgrade of luminosity with L ~ cm -2 s -1 –Aims at operation beyond ultimate luminosity (the goal is integrated L). –Implies operation in extremely radiation hard environment (35 MGy/year). –Less than 1 year lifetime for magnets with nominal triplet layout! –New magnet technology and /or special protection / absorber elements. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’073

The path to Phase 1 layout - I Technological challenge of large aperture quadrupoles (see presentation of E. Todesco): where are the limits of gradient vs. aperture? 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’074 From E. Todesco, J.-P. Koutchouk, LUMI’ 06 Proceedings

The path to Phase 1 layout - II Huge parameter space: semi-analytical approaches and fitting to determine Twiss parameters vs. free parameters 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’075 From E. Todesco, J.-P. Koutchouk, LUMI’ 06 Proceedings.

The path to Phase 1 layout - III Huge parameter space: analytical approaches applied to a slightly simplified system to fix the overall optical parameters prior to detailed analysis are needed. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’076 R. De Maria, LHC Project Report 1051.

The path to Phase 1 layout - IV Guidelines for the optical design: –Aperture is the first requirement. General criterion: 33  + 12 mm needed in the triplets Open question: how much aperture margin do we need? And what is the best use of it, e.g. –Mitigation of energy deposition issues (still to be studied in details, see presentation by E. Wildner). –Mitigation (but not solution!!!) of impedance issues due to collimators. –Keep  max under control (impact on chromaticity, off-momentum beta-beating and single-particle dynamic aperture). 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’077

The path to Phase 1 layout - V A word on off-momentum beta-beating: –Nominal LHC: 3/  p/p -> 10%/30% Correction means (see S. Fartoukh LHC Project Report 308) 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’078 –Phasing IPs –Chromatic sextupoles (32 families/beam) NB: off-momentum beta-beating can be corrected only in one half of the machine. Example from an upgrade optics

The path to Phase 1 layout - VI Apart on aperture, off-momentum beta-beating has an impact on collimation performance. How to chose in which half of the machine the beating has to be corrected? 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’079 Betatron cleaning IR Momentum cleaning IR Driving criterion: avoid that a secondary collimator becomes a primary one. FOR the nominal LHC the correction should be made between IR5 and IR1.

The path to Phase 1 layout - VII Concerning field quality issues, it is worth mentioning that: –Recently a useful result was obtained concerning the dependence of the triplets field quality on aperture (E. Todesco et al. LHC Project report 1010). –The impact of these scaling laws on dynamic aperture clearly observed (see presentation by R. Tomás). Hardware constraints such as modularity (optimize the tooling and the spares) have to be considered. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0710

The path to Phase 1 layout - VIII Putting everything together: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0711 From R. de Maria LIUWG presentation 18/10/07 Detailed discussion of the four optics under consideration for the Phase 1 upgrade by R. de Maria.

The path to Phase 1 layout - IX Usually the focus is always on the triplets, but the long straight section needs also revision and detailed analysis (see S. Fartoukh LIUWG presentation 27/09/07): –D1 (warm design): its aperture has to be increased! Modification to the current design proposed (J.-P. Koutchouk and D. Tommasini): very cost-effective. Should a cold D1 be considered? –D2, Q4, Q5: a rotation of the beam screens should fix the aperture issues. Possibility of designing a two-aperture Q4 with increased aperture assessed (E. Todesco). –The rest of the long straight section is essentially compatible with Phase 1 upgrade requirements. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0712

08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0713 The path to Phase 1 layout - X Next steps: –Convergence to a smaller number of optics candidates (two). Each should be studied in terms of: Overcome the observed limitations in the optics. Provide a complete solution compatible with the hardware constraints (cryostats parameters, instrumentation). Study tunability of the optics. Study injection optics. Study squeeze sequence. Evaluate the performance of a flat beam option. Beam-beam simulations. Collimation performance.

The beneficial effect of flat beams - I 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0714

The beneficial effect of flat beams - II 31/10/2007M. Giovannozzi – CARE-HHH-APD IR’0715

Phase 2: introduction - I Current studies look for a 10-fold increase in the peak luminosity. Two options (doubling the bunch number not possible): –ES (25 ns): –ES (25 ns): Low  * (11 cm – 14 cm) with ‘ultimate’ beam parameters requiring significant hardware modifications in the IR & detector regions. –LPA (50 ns): –LPA (50 ns): operation with larger than ‘ultimate’ beam intensities and ‘flat bunches’ but without modifications in the detector regions. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0716

Phase 2: introduction - II Additional measured required for a Phase 2 upgrade: –Upgrade of the cryogenic plants for IR1 and IR5 (additional new plants). –Improved shielding and protection of triplet magnets. –Both Phase 2 options require additional measures that go beyond magnet. –R&D and that could benefit already the Phase 1 upgrade. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0717

Phase 2: optics concept 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0718 R. De Maria, LHC Project Report 1051 Additional changes in the long straight section (see S. Fartoukh LIUWG presentation 27/09/07): Beam screen rotation in D2, Q4, Q5. Q4, Q5 must be replaced with large aperture magnets mm gap requested for D1 (cold D1 might be the only possible option) mm aperture requested for D2 (Warm D2, e.g. MBW type, might be the only possible option). J.-P. Koutchouk et al., PAC07.

Additional measures for Phase 2 - I Minimizing the luminosity loss due to the crossing angle: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0719 The crossing angle results at the IP in an increase of the effective cross section and thus a reduction of the luminosity. Assuming a constant normalized beam separation the reduction factor decreases with decreasing  * ! ** Piwinski angle F

Additional measures for Phase 2 - II Minimizing the luminosity loss due to the crossing angle at the IP: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0720 wire compensator New proposal and technology, requiring MDs (USLARP & ) Could potentially reduce the required crossing angle Similar proposal for head-on collisions: electron lens Compensate the long range beam-beam effects, thus allowing a smaller angle

Additional measures for Phase 2 - III Minimizing the luminosity loss due to the crossing angle at the IP: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0721 Requires magnet integration inside the detectors. Impact on detector performance and physics reach. Requires new magnet technology. Implies beam-beam studies (numerical and experimental). Reduce the crossing angle at the IP via dipole magnets deep inside the detectors (slim dipole option) stronger triplet magnets D0 dipole Q0 quad’s

Additional measures for Phase 2 - IV Minimizing the luminosity loss due to the crossing angle at the IP: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0722 Requires high precision RF technology and control. Currently used in KEK B-factory. No experience with operation in proton machines (noise). Requires prototyping and machine studies (lead time and resources). Bunch rotation via crab cavities. It implies a new technology for protons.

Additional measures for Phase 2 - V Minimizing the luminosity loss due to the crossing angle at the IP: 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0723 Development of a prototype ‘electron lens’ at FNAL. This new tool is currently studied / tested in Tevatron (and RHIC in 2008). Still open issues: Tevatron observes significant operation improvements (lens as a fast quadrupole), but no successful operation as beam-beam lens. Bunch rotation via crab cavities. It implies a new technology for protons. Compensate the head-on beam-beam force by additional e - /p + interactions (opposite sign of the p + /p + beam-beam force).

Additional measures for Phase 2 - VI Operation with large Piwinski angle: 40% higher luminosity for flat bunch profile. –Increased luminosity lifetime. –Does the flat bunch remain flat (proved in injectors for short times)? Luminosity leveling (see talks by J.-P. Koutchouk and G. Sterbini): Can it be performed in real operation? 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0724

Phase 2 luminosity potential reach Average luminosity over one physics run assuming optimum run length. Estimates done without luminosity leveling. Phase 2 might provide average luminosity increase by a factor 3 to 4 in most optimistic scenario. 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0725 F. Zimmermann at Beam07

Conclusions and outlook Phase 1: –Essentially new magnets are required, only. Phase 2: –New magnets are required and (not all together): Wire compensators Integrated dipole magnets Crab cavities Electron lens Longitudinal flat beam operation Luminosity leveling Magnets TAS, absorbers, and masks All additional measures for the Phase 2 upgrade could benefit the Phase 1 upgrade. They should be launched before Phase 2! 08/11/2007M. Giovannozzi – CARE-HHH-APD IR’0726