Post on 21-Jan-2020
Attività Sperimentali in Corso suRaggi Cosmici nello Spazio
Mirko BoezioINFN Trieste, Italy
Commissione Scientifica Nazionale 29 Aprile 2013
• Siti/meccanismi di accelerazione dei raggi cosmici• Propagazione nella galassia e spettri energetici• Elettroni• Ricerca indiretta di materia oscura ed
antimateria• UHECR
Desidero ringraziare i responsabili degli esperimenti, sia INFN che altri, per aver fornito le slides con l’aggiornamento dei risultati o lo stato dell’arte degli esperimenti.
An Overview
Esperimenti Linea 4Esperimenti Obiettivi Stato
AGILE Astrofisica Gamma:30 MeV – 50 GeV
In presa dati dal 2007. Non piu finanziato INFN
AMS-02 CR carichi:500 MeV – 2 TeV
In presa dati dal 2011.
Fermi Astrofisica Gamma/CR carichi: 100 MeV – 300 GeV/7 GeV – ~1 TeV
In presa dati dal 2008.
DAMPE Astrofisica Gamma/CR carichi: GeV – 10 TeV
Previsto su stazionespaziale cinese 2015. Da approvare INFN.
GAMMA-400-RD Astrofisica Gamma/CR carichi: 30 MeV – 3 TeV/GeV – PeV
Lancio previsto 2018. Approvato Russia, approvato come RD INFN.
JEM-EUSO-RD CR: >5x1019 eV Previsto su ISS 2017.WIZARD CR carichi:
50 MeV – 1 TeVIn presa dati dal 2006.
Spectra
Preliminary
Index ~ 2.1 – 2.2Little variation across SNRCutoff or break at high energy
� Acceleration ofprimary particlesin SNR shock towell beyond 100 TeV
TeV image by HESS (Aharonian et al. 2007)
Spectrum by Fermi-LAT (Abdo et al. 2011)
GeV image by Fermi-LAT (Abdo et al. 2011)
LEPTONIC EMISSION !
EXAMPLE: SNR RXJ1713.7-3946 TeV is not enough
Π0-dominant
Mixed Π0/IC
Inverse ComptonB-Field a 10 PG
AGILE intensity map, smoothing3E: 400-10000VLA contours (green)
NANTEN2 CO map41 km/s (green), 43 km/s (blue)AGILE 400-10000 cont. (magenta)VLA contours (white)
AGILE discovery of pion emissionfrom the SNR W44
Fermi: CR protons in SNR
16Detection of the pion-decay cutoff in Supernova remnants2013, Science, 339, 807
Fermi: Pass8 improvements• Current Pass8 development has major advances in
– CAL recon: multiple clusters + new full 3D shower profile recon to extend up to ~3TeV
– TKR recon: improved pat-rec to reduce PSF tails• Development heavily relies on LAT MC and data/MC agreement with
flight datasets
18
arxiv 1303.3514
Trans-Iron Galactic Element RecorderTwo balloon flights over Antarctica:• December 2001 (32 days);• December 2003 (18 days)
New ballon/borne experiment(Super-TIGER) withsignificantly larger acceptance(2.5m2sr) flew in 09-Dec-2012 –01-Feb-2013
Rauch et al., ApJ 697 (2009) 2083
10 20 30 40 50 60 70 80 90100
0.1
1
Volatile Refractory
GC
RS
/(8
0%
SS
+2
0%
MS
O)
Atomic Mass
Mg
Al
Si
P
Ca Fe
Co
Ni
Sr
NNe
S Ar Cu
Zn
Ga
Ge
Se
Refractories
Volatiles
6.9.10_Figure_for_MHI/TIG_GCRS_vs_80-20mix_rev2
Rauch et al. ApJ 697, 2083 (2009)
Ahn et al. ApJ 715, 1400 (2010)
Compare GCR source abundances with a mixture of 80% SS (Lodders) and 20% Massive Star Outflow (Woosley & Heger, Phys. Rep. 442 (2007) 269).
• Elements present in interstellar grains are accelerated more effectively than those found in the interstellar gas
• Data are consistent with the idea that OB associations are the most probable source of at least a substantial fraction of CR
H & He absolute fluxes @ high energy
Deviations from single power law (SPL):
�Spectra gradually soften in the range 30÷230GV�Spectral hardening @ R~235GV 'J~0.2÷0.3
SPL is rejected at 98% CL
Origin of the structures?- At the sources: multi-
populations, etc.?- Propagation effects?
(e.g. P. Blasi et al., Phys.Rev.Lett. 109 (2012) 061101
Sola
r mod
ulat
ion
Sola
r mod
ulat
ion
2.852.67
232 GV
Spectral index 2.772.48
243 GV
H He
O. Adriani et al., Science 332 (2011) 69Mirko Boezio, ICTP Trieste, 2012/11/19
CR PROPAGATION
C.R.E.A.M. (Ahn et al. 08)
Ge=1/3
Ge=0.7
Ge=0.6
SECONDARY TO PRIMARY RATIOS0.3<Ge<0.7
Jo= Je+Ge � Je|2-2.4
��
WESC |H2
D E� �vE-G e
��
NSEC E� �|N E� ��SPWESC vE-J inj�2G e
DISKHALO
H 2h
��
N E� �| Ns E� ��2SRd
2HWESC vE
�J inj �G e
E. Amato , APS April Meeting, Atlanta 2012
Detector Systems in CREAM-1
• TCD: Timing Charge Detector9 Trigger and Charge
• TRD: Transition RadiationDetector
9 Tracking 9 Lorentz Factor for Z t 3
CER: Cherenkov Detector–Charge/Velocity for Z t 3
calorimetermodule
From CREAM to ISS-CREAM
• The International Space Station (ISS) is nearly ideal for our quest to investigate the low fluxes of high-energy cosmic rays.
• The CREAM instrument will be re-packaged for accommodation on NASA’‛s share of the Japanese Experiment Module Exposed Facility (JEM-EF).
• This “ISS-CREAM” mission is planned for launch in 2014.
CREAM
Increase the exposure by an order of magnitude
(CREAM for the ISS)
Eun-Suk Seo
ISS-CREAM Instrument
CREAM
SCD
BCD BSD
4 layer Silicon Charge Detector- Precise charge measurements- 380-µm thick 2.12 cm2 pixels- 79 cm x 79 cm active detector area
Carbon Targets (0.5 Oint ) induces hadronic interactions
TCD
C-targets
CAL
Calorimeter (20 layers W + Scn Fibers)- Determine Energy - Provide tracking- Provide Trigger
Top & Bottom Counting Detectors- Each with 20 x
20 photodiodes and a plastic scitillator for e/p separation
- Independent Trigger
BoronatedScintillator Detector - Additional e/p
separation- Neutron
signals
Eun-Suk Seo
Gamma-400: Calorimeter Geometry
• Homogeneous calorimeter• Symmetric, to maximize the
Geometric Factor: 100x100x52 cm3
(50X0x50X0x26X0)• Total weight ~ 1800 kg• Very high dynamic range• Finely segmented in every
direction1 RM x 1 RM x 1 RM small
CSI crystals, cubic shape• Few mm gap between crystals
Experiment
Duration
Planar GF(m2
sr)
H selCalo V(E)/E
Calo depth
E > 0.1 PeV E > 0.5 PeV E > 1 PeV E > 2 PeV E > 4 PeV
H conv p He p He p He p He p He
CALET 5 y 0,120,8
~40% 30 X01,3 O0
146 138 9 10 2 3 1 1 0 00,5
CREAM 180 d 0,430,8
~45% 20 X01,2 O0
41 39 3 3 1 1 0 0 0 00,4 CT*
ATIC 30 d 0,250,8
~37% 18 X01,6 O0
5 5 0 0 0 0 0 0 0 00,5 CT*
G400 10 y 8,50,8
~17% 39 X01,8 O0
16521 15624 979 1083 261 326 60 92 10 210,4
~ knee
Counts estimation, protons and helium nuclei
* carbon target
Polygonato modelG400 configuration: CsI(Tl), 20x20x20 crystals
Size: 78.0x78.0x78.0 cm3 – gap 0.3 cmTaking into account: geometrical factor and exp. duration + selection
efficiency 80%
Electron Observations• High energy electrons have a high energy loss rate v E2
– Lifetime of ~105 years for >1 TeV electrons• Transport of GCR through interstellar space is a diffusive
process– Implies that source of high energy electrons are < 1 kpc
away
Electrons are accelerated in SNR (as seen in J-rays)
Only a handful of SNR meet the lifetime & distance criteria
Kobayashi et al (2004) calculations show structure in electron spectrum at high energy
FERMI all Electron Spectrum
A. Abdo et al., Phys.Rev.Lett. 102 (2009) 181101M. Ackermann et al., Phys. Rev. D 82, 092004 (2010)
Astrophysical Explanation:Pulsars
• Mechanism: the spinning B of the pulsar strips e- that accelerated at the polar cap or at the outer gap emitJ that make production of e± that are trapped in the cloud, further accelerated and later released at τ ~ 105 years.
• Young (T < 105 years) and nearby (< 1kpc)
• If not: too much diffusion, low energy, too low flux.
• Geminga: 157 parsecs from Earth and 370,000 years old
• B0656+14: 290 parsecs from Earth and 110,000 years old.
• Diffuse mature pulsars
CRAB NEBULA
Some structure in the curve should eventually be seen for pulsars? (D. Grasso et al., Astropart. Phys. 32, 140, 2009).
Pulsar Explanation
D. Malyshev, I. Cholis and J. Gelfand, PRD 80 (2009) 063005
Fermi: A new picture for pulsars• Emission mechanism away from star• Many J-ray only PSR• ms PSR in J-ray
– Pulsar timing array• ms PSR in globular clusters
Pletsch, H. J. et al. 2012, ApJ, 744, 105Saz Parkinson, P. M. et al. 2010, ApJ, 725, 571Abdo, A. A. et al. 2010, ApJS, 187, 460Abdo, A. A. et al. 2009, Science, 325, 840Abdo, A. A. et al. 2009, Science, 325, 845Abdo, A. A. et al. 2009, Science, 325, 848Abdo, A. A. et al. 2008, Science, 322, 1218…. plus many other2013 AAS/HEAD Rossi Prize
Science Objectives Observation Targets (5 years)Nearby Cosmic-ray Sources Electron spectrum in trans-TeV region
Dark Matter Signatures in electron/gamma energy spectra in 10 GeV – 10 TeV region
Origin and Acceleration of Cosmic Rays
Proton spectrum to ≈ 1000 TeV, spectra of C,O,Ne,Mg,Si to ≈ 20 TeV/n; Fe spectrum to ≈ 10 TeV/nUltra-Heavy Ions (26 < Z ≤ 40) E > 600 MeV/n
Cosmic –ray Propagation in the Galaxy B/C ratio up to several TeV /nucleonSolar Physics Electron flux below 10 GeVGamma-ray Transients X-rays/Gamma-rays in 7 keV – 20 MeV
z Nominal Orbit: 407 km, 51.6o inclination
z Launch carrier / plan:HTV-5 / mid 2014
z Mission Lifetime:≥ 5 years
� Mass: 650kg (Max)� Standard Payload Size� Power: 500W (Max)
CALETHigh Energy Electron
and Gamma-Ray Telescope
JEM/EF ( Exposure Facility on ISS)
CALET Instrument450 mm
Shower particles
CHD(Charge Detector)
IMC(Imaging Calorimeter)
TASC(Total AbsorptionCalorimeter)
Function Charge Measurement (Z=1-40) Arrival Direction, Particle ID Energy Measurement, Particle ID
Sensor(+ Absorber)
Plastic Scintillator : 2 layersUnit Size: 32mm x 10mm x 450mm
SciFi : 16 layersUnit size: 1mm2 x 448 mm
Total thickness of Tungsten: 3 X0
PWO log: 12 layersUnit size: 19mm x 20mm x 326mmTotal Thickness of PWO: 27 X0
Readout PMT+CSA 64 -anode PMT+ ASIC APD/PD+CSAPMT+CSA ( for Trigger)
Expected Performance( from Simulations and/or Beam Tests)
• Geometric Factor:1200 cm2sr for electrons, light nuclei1000 cm2sr for gamma-rays4000 cm2sr for ultra-heavy nuclei
• ΔE/E : ~2% (>10 GeV) for e,γ’s~30 % for protons
• e/p separation : 10-5
• Charge resolution : 0.15 - 0.3 e• Angular resolution :
0.1° for gamma-rays > ~50 GeV
- 48 -
48
Is there a nearby (< 1 kpc) acceleration source?
¾ CALET will explore the spectral shape beyond 1 TeVwith:
- Low proton background (105 rejection) achievable thanks to:
• Calorimeter depth for e.m. showers (30 X0)• High granularity of IMC pre-shower
- Excellent energy resolution (2 %) from PWO crystals
¾ CALET will perform Anisotropy measurements to validate possible evidence of nearby source(s)
Nearby Pulsar(s)or
Dark Matter ?
Vela10,000 years820 ly(by CHANDRA)
- 48Example: simulated e++e- spectrum for a decay channel of D.M.-> l+l-Qwithm = 2.5TeV and W = 2.1x1026 s
¾ Search for structures in the inclusive electron spectrum with high energy resolution
G400 configuration: CsI(Tl), 20x20x20 crystalsSize: 78.0x78.0x78.0 cm3 – gap 0.3 cm
Taking into account: geometrical factor and exp. duration + selection efficiency 80%
Experiment Duration
Planar GF (m2 sr)
Calo V(E)/E
Calo depth
e/p rejection
factorE > 0.5 TeV E > 1 TeV E > 2 TeV E > 4 TeV
CALET 5 y 0,12 ~2% 30 X0 105 3193 611 95 10
AMS02 10 y 0,5** ~2% 16 X0 103 ** 26606 5091 794 84
ATIC 30 d 0,25 ~2% 18 X0 104 109 21 3 0
FERMI 10 y
1,6@300 GeV *
0,6@800 GeV *
~15% 8,6 X0 104 59864 2545 0 0
G400 10 y 8,5 ~0,9% 39 X0 106 452303 86540 13502 1436
* efficiencies included ** calorimeter standalone
GAMMA-400 count estimation: electrons
The detector is consisted of 4 parts:Top scintillators (charge measurement)Si tracker (5 layers)BGO calorimeterNeutron detector
Comparison of Detector Performance for Electrons
Detector Energy Range(GeV)
Energy Resolution
e/p Selection Power
Key Instrument(Thickness of CAL)
SΩT(m2srday)
ATIC1+2(+ ATIC4)
10 -a few 1000
<3%( >100 GeV)
~10,000 Thick Seg. CAL (BGO: 22 X0)+ C Targets
3.08
PAMELA 1-700 5%@200 GeV
105 Magnet+IMC(W:16 X0)
~1.4(2 years)
FERMI-LAT 20-1,000 5-20 %(20-1000
GeV)
103-104
(20-1000GeV)Energy dep. GF
Tracker+ACD+ Thin Seg. CAL
(W:1.5X0+CsI:8.6X0)
60@TeV(1 year)
AMS 1-1,000(Due to Magnet)
~2-4%@100 GeV
104
(x 102 by TRD)Magnet+IMC+TRD+RICH(Lead: 17Xo)
~50(?)(1year)
CALET 1-10,000 ~2-3%(>100 GeV)
~105 IMC+CAL(W: 3 Xo+ PWO : 27 Xo)
44(1years)
DAMPE 1-10,000 ~1%(>100 GeV)
~106 IMC+CAL+Neutron(W: 2 Xo+ BGO: 32 Xo)
180(1 years)
DAMPE is optimized for the electron observation in the tran-TeV region, and the performance is best also in 10-1000 GeV.
DM annihilationsDM particles are stable. They can annihilate in pairs.
Primary annihilation channels Decay Final states
σa= <σv>
Dark Matter J Search StrategiesSatellites
Low background and goodsource id, but low statistics
Galactic CenterGood Statistics, but source confusion/diffuse background
Milky Way HaloLarge statistics, but diffusebackground
Isotropic” contributionsLarge statistics, but astrophysics, galactic diffuse background
Spectral LinesLittle or no astrophysical uncertainties, goodsource id, but low sensitivity because ofexpected small branching ratio
Dark Matter simulation:Pieri+(2009) arXiv:0908.0195
Galaxy ClustersLow background, but low statistics60
Fermi: No sign of Dark Matter yet
Ackermann, M. et al. 2011, Phys. Rev. Lett., 107, 241302
A. Albert, Fermi Symposium 2012, in preparationAckermann, M. et al. 2012, Phys. Rev. D, 86, 022002
� Search in dwarf spheroidals– Free from astro background– Current limit close to thermal
relic V <~30 GeV– Prospects to constrain WIMP
paradigm within next years
� Line search– No significant
detection– line-like feature in GC
and control samples
Antiproton Results
Donato et al. (PRL 102 (2009) 071301)
Simon et al. (ApJ 499 (1998) 250) Ptuskin et al. (ApJ 642 (2006) 902)
Cosmic-Ray Antiprotons and DM limits
D. G. Cerdeno, T. Delahaye & J. Lavalle, Nucl. Phys. B 854 (2012) 738Antiproton flux predictions for a 12 GeV WIMP annihilating into different mass combinations of an intermediate two-boson state which further decays into quarks.
See also:• M. Asano, T. Bringmann & C. Weniger, Phys. Lett. B 709 (2012) 128.• M. Garny, A. Ibarra & S. Vogl, JCAP 1204 (2012) 033• R. Kappl & M. W. Winkler, PRD 85 (2012) 123522
Cosmic-Ray Antiprotons and DM limits
M. Cirelli & G. Giesen, arXiv: 1301:7079Antiprotons are a very relevant tool to constrain Dark Matter annihilation and decay, on a par with gamma rays for the hadronicchannels. Current Pamela data and especially upcoming AMS-02 data allow to probe large regions of the parameter space.
PAMELA Positron to Electron Fraction
Preliminary
Mirko Boezio, SLAC, 2013/03/06
Secondary productionMoskalenko & Strong 98
But antiprotons in CRs are in agreement with secondary production
CR Positron spectrum significantly harder than expectations from secondary production
A Challenging Puzzle for CR Physics
Donato et al. (PRL 102 (2009) 071301)Ptuskin et al. (ApJ 642 (2006) 902)
Simon et al. (ApJ 499 (1998) 250)
A Challenging Puzzle for CR Physics
P.Blasi, PRL 103 (2009) 051104; arXiv:0903.2794Positrons (and electrons) produced as secondaries in the sources (e.g. SNR) where CRs are accelerated.
I. Cholis et al., Phys. Rev. D 80 (2009) 123518; arXiv:0811.3641v1
Contribution from DM annihilation.
D. Hooper, P. Blasi, and P. Serpico, JCAP 0901:025,2009; arXiv:0810.1527Contribution from diffuse mature &nearby young pulsars.
A second key result from Auger
Observation of anisotropy of UHE particles at E>5x1019 eV
The Auger Collaboration (2007)
Enables Particle Astronomy
What can originate such cosmic rays?• “Top-Down” scenario: Produced by early universe symmetry breaking, decay of cosmic supermassive background particles, violation of Lorentz invariance……
E or MX ≈ 1021 eV
Cosmic strings
photons
A jump in exposure is necessary
From 2x104 km2 year sr of AUGER to 106 km2 year sr
To open a new astronomical window and to go beyond the standard model of particle physics and fundamental interactions