Astroparticle Physics with AMS-02

1. Astroparticle Physics with AMS-02 Dr. C.Sbarra INFN-Bologna, Italy On behalf of the AMS collaboration 12th Lomonosov Conference, Moscow 2005

2. Outlook • The AMS experiment and its forthcoming operation on International Space Station (ISS) • The antimatter discovery potential of AMS-02 and the Baryogenesis scenarios investigated • The e+ , p , ddetection and subsequent impact on the various models of exotic physics Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

3. The Test Experiment: AMS-01 Onboard the shuttle Discovery (1998) • Results: • Environmental studies • Background studies • Fulfill the constraints from space • Antimatter/matter limit • (<1.1x10-6 at 95% C.L. PR 366/6, 2002) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

4. The AMS-02 experiment The Anti Matter Spectrometer The knowledge obtained in the precursor 10 days flight AMS-01 (1998) was used to redesign the spectrometer for the ISS: • Long exposure: > 3 years • Superconducting magnet (BL2 0.86 T, 1m3 fill volume) • Large acceptance: 0.5 m2 sr • Many repeated measurements of particle velocity, momentum and charge Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

5. The AMS-02 experiment PID : The subdetectors • Huge statistics of all type of Cosmic rays in the energy range 1 GeV – 1 TeV (/nucl) • For low rates high redundancy and precise detector measurements

6. The AMS-02 experiment PID : The subdetectors • 20 layers of TRD for e+/h sep. (1.5 -300 GeV) • 4 layers of TOF for trigger, time (150 ps), βand |Q| meas. • 8 layers of double sided Silicon tracker for p (10/30 μm res. b./non b.) and ±Q meas. • VETO Counters • RICH for β (Δβ/β~0.1%) and |Q| • 3D sampling ECAL (17X0of plastic fibers) for e+e-/h sep. (1.5 GeV-500GeV) Super conducting Solenoid (0.86 T) He vessels Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

7. The AMS-02 experiment Spectrometer Resolution (P.R. 366/6) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

8. The AMS discovery potential Antimatter in our universe • The physical laws at microscopic level are symmetric between baryons and anti-baryons • The physical Universe seems to be asymmetric (there seems to be only matter) - How can evolve an asymmetric universe (totally or even only locally) from a primordial big-bang and with symmetric laws? baryogenesis ? Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

9. Andrei Shakarov put the necessary conditions for baryogenesis [JETP Lett. 91B,24 (1967)] : Baryon number B non conservation C and CP non conservation Out of equilibrium decay - The inflation is a natural scenario where a baryogenesis can take place: it allows the out of equilibrium condition and it can avoid the a-prori hypothesis of initial symmetric conditions [L.F. Abbott et Al.,Physics Lett.117B(1982)] Antimatter in our universe: Baryogenesis Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

10. Antimatter in our universe: Baryogenesis Is the Universe globally or only locally asymmetric? • In a totally symmetric universe, high energy CRs could escape from an antimatter domain and get to our galaxy • On the basis of γ-rays observations our matter dominated region has at least the size of cluster of galaxies Is there place for antimatter in a totally asymmetric Universe as seem to be ours? Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

11. Antimatter in our universe: Baryogenesis [M. Y. Khlopov, S.G.Rubin and Al.S.Sakharov hep-ph/0210012 ] • In the matter dominated universe there is also the possibility of small insertions of antimatter regions : Quantum fluctuations of a complex, baryonic charged scalar field caused by inflation can generate antimatter regions that can survive annihilation • There can exist antistar global clusters in our galaxy • The expected signature of such scenario is a flux of 3He and 4He accessible to AMS-02 Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

12. Pamela Antimatter in our universe: Experimental searches An anti-nucleus can be found in Cosmic Rays, with a spectrometer on top of the atmosphere (balloons) or on a satellite (Pamela, AMS-02) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

13. Antimatter in our universe: Antinuclei, antiparticles • The antiparticles are “secondaries” produced by CR interactions with ISM through inelastic collisions – “spallation” Flux 4He O(10-12), D O(10-8), p O(10-4), e+ O(10-3) • But some antiparticles can be “primaries” from exotic sources of antimatter or DM annihilation (an He would be evidence of antistars) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

14. Antimatter in our universe: antiparticles - Positrons Edsjö et al • Ratio e+/(e++e-) can reveal neutralino annihilations [Phys.Rev.D 65/6] HEAT data show possible excess around ~10GeV Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

15. Antimatter in our universe: antiparticles - Positrons AMS can measure 106positrons up to 300 GeV and can confirm or not the bump • Flux ratio : p/e+ ~ 103 Strong p/e+ rejection - TRD : Rej~103/102 in 3-300 GeV - ECAL: Rej~104 for E~500 GeV (TRD + ECAL together Rej ≥ 105) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

16. Antimatter in our universe: Antideuterons • Antideuteron is to be observed in CRs D limit from Bess < 1.9x10-4 (m2 ·s·sr·GeV/n)[28th ICRC 2003] The neutralino (the lightest supersymmetric particle) would be left as relic by large amount of sparticles decayed • AMS-02 can observe O(10) low momentum D from neutralino annihilation [F.Donato et Al.1999] Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

17. Antimatter in our universe: Antideuterons • The known ratio of D/p is ~ 10-5in the observed universe • AMS-02 can detect D from antimatter domains : D/p ~ 10-5(AMS-01 observed ~100 p, thus D was unobservable) The ratio of primordial He to D is ~ 104 and in CR it is about 10 thus any D from antimatter domain would be accompaigned by He or p Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

18. Antimatter in our universe: Antiprotons • Antiproton flux O(10-4) at E~1 GeV (e-/p ~ 103 at E ~ 1 GeV strong e-/p rejection at this energy) • Antiprotons in CRs have been detected up to O(10 GeV) and all seem to be compatible with secondary production Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

19. Antimatter in our universe: Antiprotons • Simulation of three years of high statistics measurements of antiproton spectrum • AMS-02 will be able to detect antiprotons up to 400GeV [V.Choutko,Nucl.Phys.B Proc.Suppl.113-2002] Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

20. Antimatter in our universe: Antiprotons • Proton rejection: good control of charge confusion, interaction with the detector and misreconstructed tracks • Electron rejection: use TOF + RICH beta measurements at low energies, TRD and ECAL rejection capability at high energy Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

21. Wolfendale & Stecker hypothesis[19th ICRC proc. p.354]: We know that the mean lifetime of a CR in the galaxy falls with energy as E-δ with δ~0.7 If antiprotons are produced and accelerated in an antimatter domain as the protons are in our galaxy The antiproton/proton ratio , at high energies, would go~ Eδ with δ~ 0.7 , the antiprotons being mainly extragalactic and the protons galactic Antimatter in our universe: Antiprotons Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

22. Antimatter in our universe: Antiprotons [data from Golden, Buffington, Bogolmolov] • Primary hypothesis: p/p E0.7 From Stecker & Wolfendale, 19th ICRC (La Jolla) 1985, OG6.1-8, p354 • At energy E>100GeV the experimental data could discriminate between primary and secondary hypothesis Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

23. AMS-01 [V.Choutko] Antimatter in our universe: Antiprotons • Most recent data on p/p [by Picozza and Morselli J.Phys.G: Nucl.Part.Phys.29 (2003)] • Superimposed extragalactic hypothesis, black hole evaporation model, secondary production • More data could discriminate between the various models for E >10GeV Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

24. Antimatter in our universe: Antiprotons • As other antiparticles, antiprotons at lower energy could reveal neutralino annihilation: • χχ WW,.. e+, p, D, γ… ( Indirect search in several channels ) • Flux of products depends on neutralino density, CRs propagation terms,.. Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

25. Signal : 1) M=964 GeV (4200) 2) M=777 GeV (1200) Antimatter in our universe: Antiprotons Ullio (1999) • Antiprotons are particularly sensitive to the physics details of CR propagation (controlled by B/C ratio), particularly at low momentum Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

26. Conclusion • The AMS-02 spectrometer will measure CRs fluxes with high precision for more than three years • AMS-02 will be sensitive to antinuclei up to 100 Mpc of distance • AMS-02 can discriminate between a totally symmetric or an antisymmetric universe also through antiprotons at E >100GeV • AMS-02 will have the sensitivity to detect the products of DM annihilation in our galaxy through positrons, antideuterons and antiprotons at O(GeV) energy Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

27. SLIDES EXTRA

28. The AMS-02 experiment Operation in Space constraints • Thermal range (day/night ΔT~1000 ) • Vibration (6.8 G RMS) and G-Forces (17 G, 9 G take off) • Weight limitation (7000 kg) • Power limitation (2000 W) • Vacuum: < 10-10 Torr • Radiation ionizing flux ~1000 cm-2s-1 • Orbital debris and micrometeorites • Must operate without human intervention (Redunduncy) Dr.C.Sbarra, INFN-Bologna, Italy 12th Lomonosov Conference, Moscow 2005

30. AMS-01 p/pbar all recent + Ams01

31. p/pbar – all recent data

32. Energy resolution (from Palomares) (E)/E ~ 3% for 100 GeV electrons

33. The AMS-02 experiment AMS –γ :2 modes detection Converted  : Detection of the e+e- pair in the tracker Calorimeter : Standalone trigger

34. The AMS-02 experiment Energy Resolution ….

35. The AMS-02 experiment Angular Resolution (tracker)