LHCf: stato e programmi

1. Oscar Adriani University of Florence & INFN Firenze LHCf: stato e programmi INFN CSN1 Bologna, 18 Settembre 2013

2. Hadronic models tuning after the first LHC data (for VHECR) Xmaxas function of E and particle type Post LHC Pre LHC PROTON Auger Coll. ICRC2011 IRON 1018 1019 T.Pierog, Cosmic QCD 2013 conference in Paris O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

3. Hadronic models tuning after the first LHC data (for VHECR) Xmaxas function of E and particle type Post LHC Pre LHC PROTON Auger Coll. ICRC2011 IRON LHC is really useful!!!!!!! 1018 1019 T.Pierog, Cosmic QCD 2013 conference in Paris O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

4. LHCf Physics Program O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

5. A short review of already published results Inclusive photon spectrum analysis at 7 TeV and 900 GeV Forward p0 spectra at 7 TeV “Measurement of zero degree single photon energy spectra for √s = 7 TeV proton-proton collisions at LHC“ PLB 703 (2011) 128 “Measurement of zero degree single photon energy spectra for √s = 900 GeV proton-proton collisions at LHC“ PLB 715 (2012) 298 “Measurement of forward neutral pion transverse momentum spectra for √s = 7TeV proton-proton collisions at LHC“ PRD 86 (2012) 092001 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

6. DATA vs MC : comp. 900GeV/7TeV • None of the model nicely agrees with the LHCF data • Here we plot the ratio MC/Data for the various models • > Factor 2 difference η>10.94 8.81<η<8.9 7TeV 900GeV O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

7. DATA : 900GeVvs 7TeV Coverage of 900GeV and 7TeV results in Feynman-X and PT XF spectra : 900GeV data vs. 7TeV data 900GeVvs. 7TeVwith the same PT region Preliminary small-η Data 2010 at √s=900GeV (Normalized by the number of entries in XF > 0.1)Data 2010 at √s=7TeV (η>10.94) • Normalized by the number of entries in XF > 0.1 • No systematic error is considered in both collision energies. Good agreement of XF spectrum shape between 900 GeV and 7 TeV.weak dependence of <pT> on ECMS O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

8. p0 PT spectra for various y bin: MC/data DPMJET 3.04 QGSJETII-03 SIBYLL 2.1 EPOS 1.99 PYTHIA 8.145 EPOS gives the best agreement both for shape and yield. MC/Data 0 PT[GeV] 0.6 0 PT[GeV] 0.6 0 PT[GeV] 0.6 MC/Data 0 PT[GeV] 0.6 0 PT[GeV] 0.6 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013 0 PT[GeV] 0.6

9. p0analysis at √s=7TeV Submitted to PRD (arXiv:1205.4578). pT spectra vs best-fit function Average pT vs ylab PLB 242 531 (1990) YBeam=6.5 for SPS YBeam=8.92 for7 TeV LHC ylab = ybeam - y 1. Thermodynamics (Hagedron, Riv. NuovoCim. 6:10, 1 (1983)) • Systematic uncertainty of LHCf data is 5%. • Compared with the UA7 data (√s=630GeV) and MC simulations (QGSJET, SIBYLL, EPOS). • Two experimental data mostly appear to lie along a common curve→ no evident dependence of <pT> on ECMS. • Smallest dependence on ECMS is found in EPOS and it is consistent with LHCf and UA7. • Large ECMS dependence is found in SIBYLL 2. Numerical integration actually up to the upper bound of histogram O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

10. On going analysis Neutrons at 7 TeV ppcollisions The 2013 p-Pb run O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

11. Muon excess at Pierre Auger Obs. • Auger hybrid analysis • event-by-event MC selection to fit FD data (top-left) • comparison with SD data vs MC (top-right) • muon excess in data even for Fe primary MC • EPOS predicts more muon due to larger baryon production • => importance of baryon measurement Pierre Auger Collaboration, ICRC 2011 (arXiv:1107.4804) Pierog and Werner, PRL 101 (2008) 171101 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

12. The challenge of n analysis MC • Very big discrepancies between modelsUseful measurement! • Performance for neutrons • 35% Eres • 1mm Position Res. @ 1.5TeV n And…. Detector performanceis also interaction model dependent. • Unfolding is essential to extract physics results from the measured spectra Detector performance O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

13. Neutron identification L20% L90% • Particle Identification with high efficiency and small contamination is necessary • A 2D method based on longitudinal shower development is used • L20%(L90%): depth in X0 where 20% (90%) of the deposited energy is contained • L2D=L90%-0.25 L20% • Mean purity in the 0-10 TeV range: 95% • Mean efficiency: ~90% Shower developmentin the small calorimeter tower projection along the sloped line Layer[r.l.] L90% hadron photon L20% L2D O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

14. Preliminary n spectrum ` Large tower 7 TeVpp Small tower 7 TeVpp No efficiency correction No rapidity selection No unfolding No systematic errors Unfolding is in progress….. A paper for n performances is in preparation O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

15. Arm1-Arm2 comparison O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

16. p IP1 IP2 IP8 Arm2 Pb The 2013 p-Pb run at sNN = 5 TeV(Italian responsibility) • 2013 Jan-Feb for p-Pb/Pb-p collisions • Installation of the only Arm2 at one side (silicon tracker good for multiplicity) • Data both at p-side (20Jan-1Feb) and Pb-side (1fill, 4Feb), thanks to the swap of the beams • Details of beams and DAQ • L = 1x1029 – 0.5x1029cm-2s-1 • ~200.106 events • b* = 0.8 m, 290 mradcrossigangle • 338p+338Pb bunches (min.DT = 200 ns), 296 colliding at IP1 • 10-20 kHz trig rate downscaled to approximately 700 Hz • 20-40 Hz ATLAS common trig. Coincidence successful! • p-p collisions at 2.76 TeV have also been taken 3.5cm,4.0cm O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

17. Physics in pA QGSJET II-04 All η 8.81<η<8.99 η>10.94 p-p p-N p-Pb Nuclear effect in the forward particle production Photon spectra for different impact parameters Please observe that the impact parameter can be obtained from Atlas Lucid, for ex.! (Courtesy of S.Ostapchenko) Frankly speaking…… No big feedback from ATLAS…. Photon spectra at different η in p-p, p-N and p-Pb collisions Is p-Pbgood test for p-atmosphere? O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

18. Impact points and beam center 2d distribution of impact point: neutrons are more peaked 2013 p-Pb run  n p-remnant side DATA Determination of the beam center (BC) DATA 2d gaussian fit Coordinates of the beam center with respect to the expected beam center DATA n O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

19. g and n impact point distributions (p-remnant) PRELIMINARY PRELIMINARY Photon - x Photon - y Neutron - x Neutron - y PRELIMINARY PRELIMINARY Forward baryon production is important to understand the muon excess [T. Pierog, K. Werner PRL 101 171101(2008)] Neutrons are well peaked at the beam center O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

20. p-Pbrun: g spectra • Detailed simulations with the available hadronic interaction models are on-going for a comparison with data • Transportation of secondary particles from IP to detector, beam pipe structure, magnetic fields along the path and detector’s response will be taken into account • Vertical bars: statistical errors PRELIMINARY 32 mm PRELIMINARY 25 mm O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

21. p-Pb run: p0 PRELIMINARY PRELIMINARY O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

22. The status of the upgrades • Arm1 and Arm2 are currently dismounted in Florence • Calorimeter radiation hardening by replacing plastic scintillator with GSO is in progress • Production and laboratory tests of the new scintillators in Japan is finished both for Arm1 and Arm2 • Beam test at Ion facility (HIMAC) has been done in August 2013 • Upgrade of the silicon positioning measurement system under way • Rearranging Silicon layers for independent precise energy measurement • Increase the dynamic range to reduce saturation effects • New silicon hybrids and Kaptons are ready • The assembly of new silicon modules is starting • Test Beam at LNS for the absolute energy calibration of the silicon system has been assigned for 2014 • Summer 2014: assembly of Arm1 and Arm2 in Florence • Test beam at SPS in Autumn 2014 • Re-installation in LHC at the end of 2014 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

23. Silicon Calibration program at LNS • Aim of the test • Absolute energy calibration of one silicon module by measuring the output signal vs deposited energy • Relative energy calibration of all PACE3 chips (96) for all the eight silicon modules • Scan one module at different X-Y positions to check for systematic effects • To calibrate the silicon response we need to use different species of highly penetrating ions, allowing to span the whole energy range measurable with the PACE3 chips • To select the ions that show a constant energy loss whilst traversing the module we have set-up a simulation of the silicon detector module using the SRIM package 1 MIP = 0.043 eV/A PACE3 saturation ~600 MIP silicon silicon 12C 62 MeV/A 16O 62 MeV/A

24. 1. Absolute energy calibration • One module is centered on the beam spot and a scan with different energies/sources is done to cover the whole dynamic range from ~ 5-10% to 120% of PACE3 chip (10K events per point) • Beam energies/source are a compromise between the need to cover the full range and the availability and feasibility of the test at the LNS facilities • Only gaseous sources have been selected and only two different energies Intensity <104-106pps

25. x-stage Silicon module Flat cable To DAQ system Support box 2. Relative calibration of each PACE3 chip • A position scan (X-scan) through the 12 PACE3 x 8 modules should be done with an ion beam able to give ~ 0.2-0.3 PACE3 saturation (12C 45MeV/A or 13C 62 MeV/A or 14N 62 MeV/A are equivalent) • 10K events per position (10 minutes each including set-up time) • Beam spot size ~ 2-3 mm is required 2 BTU Required y-stage Intensity <104-106pps CS beam

26. x-stage Silicon module Flat cable To DAQ system Support box 3. Position scan along one strip – Y scan • A position scan along one strip should be done with same beam as point 2. • Useful to check for possible inhomogeneity due to the strip geometry • 10 K events x 6 positions every 10 mm (60 mm long strip) for 10 minutes each including set-up time • Beam spot size ~ 2-3 mm is required <0.5 BTU Required Intensity <104-106pps y-stage CS beam

27. LNS panel evaluation LHCf-SiCal The PAC has been convinced that absolute energy calibration of the LHCf silicon detectors is important. The collaboration did an effort to reduce beam preparation in their final demand. 4 BTU of 45 A.MeV beams are allocated: 0.25x (20Ne, 16O, 14N, 4He, 13C) BTU plus 2.75 BTU of 13C. Beam attribution: 4 BTU (45 A.MeV, see text) Preferred period: Beginning of run period (May 2014)

28. LHCf: future plan p-p at 13TeV (2015) Main target: measurement at the LHC design energy.Study of energy scaling by comparison with √s = 900 GeV and 7 TeV data Upgrade of the detectors for radiation hardness. p-light ions (O, N) at the LHC (2019?) It allows studying HECR collisions with atmospheric nuclei. • p-p collisions: • Max. √s = 500 GeV • Polarized beams • Ion collisions: • Au-Au, d-Au • Max. √s = 200 GeV • Possible, d-O,N (p-O,N)Cosmic ray – Air @ knee energy. 10cm detector O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013 RHICf experiment at RHIC Lower collision energy, ion collisions.LOI to the RHIC committee submitted

29. Physics of RHICf • Physics of RHICf • Energy Scaling of Very Forward at p-p √s=500GeV • Measurement at p-light ion collisions (p-O) √sNN=200GeV • Asymmetry of Forward Neutron with polarized beams • LOI submitted to the RHIC committee and nicely appreciated Nuclear modification factor at d-Au 200GeV

30. Conclusions • We have published spectra of photons and neutral pions for pp interactions at s = 900 GeV and s = 5 TeV • None of the hadronic interaction models that we have considered can reproduce the data within the errors, but data lie anyway between the models • On-going data analysis for the hadronic component (neutrons) • p-Pb run at the beginning of 2013 • Successful data taking in p-remnant and Pb remnant side • Common operations with ATLAS (trigger exchange) • On-going data analysis (some hints for interesting results!!!) • Future plan • Continue and finalize the on-going data analysis (start also ATLAS/LHCf common analysis) • Complete the upgrade of the detectors for radiation hardness • Beam test at LNS for silicon calibration • Data taking for pp collisions at s = 13 TeV (2015) • Run p-light ions at LHC (2019?) • Operations at RHIC (p-O or p-N at lower energies) • E …. Buonlavoroallanuovaresponsabilenazionale A. Tricomi!!!!! O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

31. Backups O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

32. Proceedings in 2013 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

33. Conferences in 2013 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

34. Playing a game with air shower (effect of forward meson spectra) • DPMJET3 always over-predicts production • Filtering DPMJET3 mesons • according to an empirical probability function, divide mesons into two with keeping pT • Fraction of mesons escape out of LHCf acceptance • This process • Holds cross section • Holds elasticity/inelasticity • Holds energy conservation • Changes multiplicity • Does not conserve charge event-by-event pT E1 E2 E=E1+E2 xF = E/E0 xF = E/E0 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

35. An example of filtering Vertical Depth (g/cm2) DPMJET3+filter photon spectrum ~30g/cm2 π0 spectrum 2.5x1016eV proton AUGER, ICRC 2011 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013 EPS-HEP 2013 July 18-24

36. η 8.5 ∞ Front view of calorimeters @ 100μrad crossing angle What LHCf can measure beam pipe shadow Energy spectra and Transverse momentum distribution of • Gamma-rays (E>100GeV,dE/E<5%) • Neutral Hadrons (E>a few 100 GeV, dE/E~30%) • π0 (E>600GeV, dE/E<3%) at pseudo-rapidity range >8.4 Multiplicity@14TeV Energy Flux @14TeV High energy flux !! Low multiplicity !! simulated by DPMJET3 O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

37. Comparison wrt MC Models at 7 TeV DPMJET 3.04 SIBYLL 2.1 EPOS 1.99 PYTHIA 8.145 QGSJET II-03 Magenta hatch: MC Statistical errors Gray hatch : Systematic Errors O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

38. Comparison wrt MC Models at 900 GeV O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

39. h Mass Arm2 detector, all runs with zero crossing angle True hMass: 547.9 MeV MC Reconstructed hMass peak: 548.5 ± 1.0 MeV Data Reconstructed hMass peak: 562.2 ± 1.8 MeV (2.6% shift) O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

40. π0 analysis at √s=7TeV Submitted to PRD (arXiv:1205.4578). Type-I Type-II • Small angle • large BG • Low-stat., but can cover • High-E • Large-PT • Large angle • Simple • Clean • High-stat. Type-ILHCf-Arm1 Type-IILHCf-Arm1 LHCf-Arm1Data 2010 Preliminary Type-II at large tower BG Type-II at small tower Signal O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

41. p0 Data vs MC O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

42. p0 Data vs MC • dpmjet3.04 &pythia 8.145 show overall agreement with LHCf data for 9.2<y<9.6 and pT<0.25 GeV/c, while the expected p0 production rates by both models exceed the LHCf data as pT becomes large • sibyll 2.1 predicts harder pion spectra than data, but the expected p0yield is generally small • qgsjet II-03 predicts p0 spectra softer than LHCf data • epos 1.99 shows the best overall agreement with the LHCfdata. • behaves softer in the low pT region, pT< 0.4GeV/c in 9.0<y<9.4 and pT <0.3GeV/c in 9.4<y<9.6 • behaves harder in the large pT region. O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

43. MC study of n response E vs. <Evis> at center Energy resolution (uniform incident on calorimeters) Position resolution Correction for position dependent shower leakage O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

44. Proton remnant side – Photonspectra O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

45. Proton remnant side - Neutronspectra O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

46. Proton-remnant side – p0 We can detect p0! Important tool for energy scale And also for models check….. O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

47. Lead-remnant side – multiplicityPlease remind that EPOS does not consider Fermi motion and Nuclear Fragmentation Small tower Big tower  n O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

48. Common trigger with ATLAS MC impact parameter vs. # of particles in ATLAS LUCID LHCf forced to trigger ATLAS Impact parameter may be determined by ATLAS Identification of forward-only events O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

49. 140 m 140 m γ 8 cm 6 cm n γ π0 Arm#2 Detector 25mmx25mm+32mmx32mm 4 X-Y Silicon strip tracking layers Arm#1 Detector 20mmx20mm+40mmx40mm 4 X-Y SciFitracking layers LHCf: location and detector layout Detector II Tungsten Scintillator Silicon mstrips Detector I Tungsten Scintillator Scintillatingfibers INTERACTION POINT IP1 (ATLAS) Front Counter Front Counter 44X0, 1.6 lint Energy resolution: < 5% for photons 30% for neutrons Position resolution: < 200μm (Arm#1) 40μm (Arm#2) Pseudo-rapidity range: η > 8.7 @ zero Xing angle η > 8.4 @ 140urad O. Adriani LHCf: Stato e Programmi Bologna, 18 Settembre 2013

50. Radiation hardness of GSO Dose rate=2 kGy/hour (≈1032cm-2s-1) • No decrease up to 1 MGy • +20% increase over 1 kGy (τ=4.2h recovery) • 2 kGy is expected for 350nb-1 @ 14TeV pp) Irradiated sample Not irradiated ref. sample １kGy K. Kawadeet al., JINST, 6, T09004, 2011 τ~4.2h recovery