BEAM DYNAMICS STUDIES FOR HILUMI LHC BARBARA DALENA IN COLLABORATION WITH: J. PAYET, A. CHANCÉ, O. GABOUEV 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 7 Capacities Specific Programme, Grant Agreement 284404. www.cea.fr SACLAY 2014 8 JANVIER 2014 CEA January 2014 PAGE 1
CONTENTS The HiLumi project Optics design IR1/5 (ATLAS and CMS) matching sections layout for crab cavity operation Non linear beam dynamics Non linear fringe field effects of large aperture magnets @ SACM/LEDA Conclusion & Outlook 8 JANVIER 2014 CEA January 2014 PAGE 2
HL-LHC Goal: integrated luminosity ~250 fb -1 / y (~10 times higher than present) New Optics Scheme Achromatic Telescopic Squeezing (ATS) IR5 Hardware changes (Nb 3 Sn superconducting technology, crab cavities) Luminosity Leveling IR1 Luminosity (cm-2 s-1) 1.E+35 8.E+34 6.E+34 4.E+34 2.E+34 Average 1035 35 34 - no level Level at 5 10 no level Average level Transverse deflecting crab cavity LARP Nb3Sn quadrupole 0.E+00 0 5 10 15 20 25 8 JANVIER 2014 CEA January 2014 PAGE 3 time (hours)
HILUMI WORKING PACKAGES HiLumi LHC WP1 Project Management and Technical Coordination WP2 Accelerator Physics and Performance WP3 Magnet Design CEA-Irfu SACM/LEDA CEA-Irfu SACM/LEAS WP4 Crab Cavities WP5 IR Collimation WP6 Cold Powering WP2.task 2: Optics & Layout close collaboration with CERN Optics option with 170 T/m triplet gradient and 120 mm aperture IR1/5 matching sections layout for crab cavity operation WP2.task 3: Tracking Field quality of HL-LHC magnets Non linear fringe field effect of large aperture magnets close collaboration with Manchester University and CERN 8 JANVIER 2014 CEA January 2014 PAGE 4
OPTICS & LAYOUT CEA January 2014 PAGE 5 8 JANVIER 2014
OPTIMIZATION FOR CRAB CAVITY OPERATION Reduce the voltage of the crab cavity: V 1/(β crab β IP ) 1/2 D2 CRAB Q4 Q5 Q6 Q7 ~150 m to IP LHC HL-LHC baseline increasing the beta function at the CRAB Q4 MQY, G=160 T/m @4.5 K = 70 mm, L = 3.4 m MQYY, G=120 T/m @1.9 K = 90 mm, L = 3.5 m using quadrupole types Q5 MQML, G=160 T/m @4.5 K = 56 mm, L = 4.8 m MQYL, G=160 T/m @4.5 K = 70 mm, L = 4.8 m quadrupole positions Q6 MQML, G=160 T/m @4.5 K = 56 mm, L = 4.8 m idem Q7 2 MQM, G=200 T/m @1.9 K = 56 mm, L = 3.4 m idem 8 JANVIER 2014 CEA January 2014 PAGE 6
PROPOSED IR1/IR5 MATCHING SECTION LAYOUT D2 CRAB Q4 Q5 Q6 Q7 ~150 m to IP baseline new proposed by SACM D2 CRAB Q4 Q5 Q6 Q7+ Q7 ~150 m to IP 15.2 m 36.6 m 15.05 m 5.595 m 8 JANVIER 2014 CEA January 2014 PAGE 7
GAIN Horizontal crossing Vertical crossing Left/Right side Baseline [MV] Proposed [MV] Proposed non ATS [MV] IR5 beam 1 10.8/12.0 8.9/8.8 8.8/9.4 IR5 beam 2 12.0/10.8 8.8/8.9 9.4/8.8 IR1 beam 1 11.8/10.8 8.7/8.9 9.3/8.6 IR1 beam 2 10.8/11.8 8.9/8.7 8.6/9.3 Few changes in the interaction region layout several benefits: Possibility to reduce the crab voltage of > 20% Compatible with low β IP at injection (5m) Compatible with the new optics scheme (ATS) Possibility to squeeze to very low β IP (non ATS) Drawbacks: Matching section apertures closer to the beam stay clear limit Additional hardware required (Q7+) 8 JANVIER 2014 CEA January 2014 PAGE 8
NON LINEAR BEAM DYNAMICS CEA January 2014 PAGE 9 8 JANVIER 2014
INNER TRIPLET NON LINEAR FRINGE FIELD EFFECT The HL-LHC project relies on large aperture magnets (due to increased beam sizes before the IP) The beam is much more sensitive to nonlinear perturbations in this region. The duodecapole component of the fringe field in the original design of LHC inner triplet was found to reduce of a factor 5 the dynamic aperture (Venturini et al.) Present design for the HL-LHC inner triplet shows an important duodecapole component of the fringe field Courtesy of M. Segreti (CEA SACM/LEAS) fringe field modeling studies and integration in SixTrack ( CERN code used to perform dynamic aperture studies ) Ultimate Goals Definition of field quality and corrections Provide feedback to the designers of magnets 8 JANVIER 2014 CEA January 2014 PAGE 10
FROM 3D MAGNETIC FIELD DATA TO TRACKING Computed B Field map Cartesian coordinates Harmonic analysis Fourier integrals Interpolation Field Harmonics Lie Tracking Transfer map of the z-dependent Hamiltonian Vector Potential A Gradient extraction Fourier Transform Inverse FT Frequency resolution (step in z dependent) Internship Master 2 Oleg Gabouev 8 JANVIER 2014 CEA January 2014 PAGE 11
MODEL VALIDATION & DISCUSSION Lie Tracking has been validated against a symplectic 4 th order integrator (RK4) for the design of different magnets 8 JANVIER 2014 CEA January 2014 PAGE 12
MODEL VALIDATION & DISCUSSION Lie Tracking has been validated against a symplectic 4 th order integrator (RK4) for the design of different magnets Lie Tracking compared to analytical kicks model shows differences related to the actual shape of the magnet fringe field 8 JANVIER 2014 CEA January 2014 PAGE 13
MODEL VALIDATION & DISCUSSION Lie Tracking has been validated against a symplectic 4 th order integrator (RK4) for the design of different magnets Lie Tracking compared to analytical kicks model shows differences related to the actual shape of the magnet fringe field Integration in SixTrack under discussion try to find the best compromise between computational speed and actual field ends shape 8 JANVIER 2014 CEA January 2014 PAGE 14
CONCLUSION & OUTLOOK WP2 activities @ CEA-Irfu: Alternative optics of the high luminosity matching sections is studied crab cavity voltage gain > 20% more flexibility in collision optics Investigation of injection and transition to collision optics Non linear fringe field effects for the large aperture quadrupoles of the interaction regions is investigated model developed and validated implementation in SixTrack on going Evaluation of the effect on long-term beam dynamics HL-LHC @ CEA-Irfu: Keep on beam dynamics and machine development studies to prepare the LHC for the High Luminosity physics program Participate to the design of future colliders 8 JANVIER 2014 CEA January 2014 PAGE 15
Thank you for your attention PAGE 16 CEA January 2014 Commissariat à l énergie atomique et aux énergies alternatives Centre de Saclay 91191 Gif-sur-Yvette Cedex T. +33 (0)1 69 08 61 97 F. +33 (0)1 69 08 64 42 Direction DSM Département Irfu Service SACM 8 JANVIER 2014 Etablissement public à caractère industriel et commercial RCS Paris B 775 685 019
INNER TRIPLET DESIGN Susana Izquierdo Bermudez (CERN) G=140 T/m, = 150 mm Prototype scaled version dx:dy:dz 3 : 3 : 5 [mm] Harmonics Old map February 2013 B6 28.24 B10 3.91 B14 0.80 B18 1.76 B22-0.18 B26-0.015 17