fine structure, mass composition, peaks Л.Г.Свешникова
TRANSCRIPT
Fine structure, mass composition, peaks
Л.Г.Свешникова
105 106 107 108 109 1010
-1,0
-0,5
0,0
0,5
Tibet (E-->E*1.26 in theory
F(E
)/A
e3-1
E, GeV
Galstr Tibetst EEr2 MGUstr Er3 ### ### ### ### ### ### ### ### ###
105 106 107 108 109 1010
-1,0
-0,5
0,0
0,5
Tibet, MSU (E-->E*1.26 in theory
F(E
)/A
e3-1
E, GeV
Galstr Tibetst EEr2 MGUstr Er3 ### ### ### ### ### ### ### ### ###
105 106 107 108 109 1010 1011
-1,0
-0,5
0,0
0,5
EAS TOPTunka
F(E
)/A
e3-1
E, GeV
Galstr Grandest B Tun133st C Tun25str B EasTpst Hires1st er2 KaskadeStr ### ### ###
105 106 107 108 109 1010 1011
-1,0x100
-5,0x10-1
0,0
5,0x10-1
Kaskade GrandeEas Top
F(E
)/Ae3
-1
E, GeV
Tibet
Kascade Grande
MSU
EAS TOPTUNKA
GAMMAF(E)/AE-2.9 -1 and TUNKA
STRUCTURE: F(E)/AE-3 -1knees and pronounced peak,
GAMMAF(E)/AE-3.0 -1
Line- our model – one of calculated variants
Basic MODEL:V. Ptuskin, V. Zirakashvili, and Eun-Suk Seo, Spectrum of galactic cosmic rays accelerated in supernova remnants. Astrophysical J. T. 718 p. 31–36.
Several types of SNR:• 1. Type Ia SNRs (Emax~4Z PeV) with
the following parameters: kinetic energy of explosion E = 1051erg, number density of the surrounding interstellar gas n = 0.1 cm−3, and mass of ejecta Mej = 1.4Ms can accelerate particles to the energy of the knee.
• 2. Type Ib/c SNRs (Emax~1Z PeV) with E = 1051 erg exploding into the low density bubble with density n = 0.01 cm−3 formed by a progenitor star as a Wolf-Rayet star. The ejecta mass is Mej = 2Ms and k = 7.
• 3. Type IIP SNRs (Emax~0.1Z PeV) with parameters E=1051erg, n = 0.1 cm−3, Mej = 8M, and k = 12.
• 4. Type IIb SNRs (Emax~600Z PeV) with E = 31051 erg, n = 0.01cm−3, and Mej = 1Ms. Before entering the rarefied bubble, the blast wave goes through the dense wind emitted by the progenitor star during its final RSG stage of evolution. It was assumed that the mass loss rate by the wind is M˙ = 10−4M yr−1 and the outer wind radius is 5 pc.
In this model sources are distributedcontiniously, the random nature of sourcesIs not considered
Extension of this model takes into account a statistical nature of sources:
Distant and old sources are simulated randomly
Nearby (Rnear~1.-1.5 кпс) and Young Tnear~105 лет) are taken
from gamma astronomy catalogs
The propagation time of 4 PeV protons is around 104 years (less than survival time of shells and PWNs, so we try to identify gamma-atronomy detected source and cosmic ray source.
Additional suggestings:1) All SNR Ia (thermonuclear explosions accelerate up to
Emax =4 PeV (23%)
2) Collapsing SNR II, SNIbc have distributed Emax from 1 TeV to 1000 TeV:
This results in additional d ~0.17, and observed near Earth
obs= sour + d+ dprop ~2.705
sour=2.2.
3) and 2-5 % SNIIn accelerated up to 6 1017 eV.
3) Chemical composition: 37% of H, 35% of He, 8% CNO, 10% of CNO, 8 % of intermediate nuclei, 10% of Fe.
Spectrum without propagation
103 104 105 106 107 108 109 1010 1011109
1010
1011
1012
with bumpbefore Emax
no peak
Protons
Sn_IIn(Emax=600 PeV)
Sn_Ia (Emax=4 PeV)
F=E-2.2 (1 +(E/Ek))c/
F(E
) E
2.2
E, GeV
• Structures can be explained only if the cutoff in source spectrum is strong d>2.5 -3.0
• Fe - peak can be explained only if we suggest “bump” before cutoff energy
Main variant
104 105 106 107 108 109 1010 1011 1012104
105
106
107
108
3.38E6
Pure Galactic
0.20
E2knee=600
Sum Gal+Metag 025
F(E
) E3.
0
E, GeV
• 1) bump around 4 PeV is produced by proton and helium nuclei with nearly equal abundances
• 2) concavity above 1016 eV denotes the transition to CNO and more heavier nuclei, the amount of Fe nuclei at that should be not less than 1/3 of He nuclei.
• 3) sharp break around the 108 GeV marks the transition to the contribution of rare SNIIb being able to accelerate protons up to 6x1017 eV comprising the several percents among all SNR. The slope of spectrum (-3.24+-0.08 in KG) in the model is connected with the slope of cutoff.
• 4) If we exclude SNIIb we can not describe the flat spectrum above the 1016 eV.
• 5) Two variant of calculation: Main 1 (absence of SNRs in the Earth vicinity with Emax=4 PeV) and Main 2 (where 4 SNRs accelerate to 4 PeV) give more or less similar structures around the knee
Here we need to knowMetaGalactic
PHe
C,O
Fe
Si
Total all particle spectrum in our model ( F(E)*E3) has fine structures
Galactic sources
Contribution of nearby actual sources
103 104 105 106 107 108 10910-2
10-1
100
101
F(E
) E2
.7
E, GeV
Main 2 all p he cno si fe nearby
Main 1 all nearby
Variant 1: No one SNR <1 kpc can accelerate to 4 PeVTotal contruution:7% in total
Variant 2: all pure shell SNRs < 1 kpc accelerate to 4 PeVTotal contribution30% in total
We did not find the actual single sources that can imitate the fine structure
Variant without “bump” in source spectrum can not describe Fe-peak, but describe structures
103 104 105 106 107 108 109 1010 1011109
1010
1011
1012
with peak
no peak
Protons
Sn_IIn(Emax=4x150 PeV)
Sn_Ia (Emax=4 PeV)
F=E-2.2 (1 +(E/Ek))c/
F(E
) E
2.2
E, GeV
Variant with wide (0.5 order) “bump” in source spectrum can describe Fe-peak more or less
103 104 105 106 107 108 109 1010 1011109
1010
1011
1012
with peak
no peak
Protons
Sn_IIn(Emax=4x150 PeV)
Sn_Ia (Emax=4 PeV)
F=E-2.2 (1 +(E/Ek))c/
F(E
) E
2.2
E, GeV
Variant with narrow (0.25 order) “bump” in source spectrum can describe Fe-peak completely, but there is a some contradiction with the main knee – it becomes too narrow and with 2 ears
103 104 105 106 107 108 109 1010 1011109
1010
1011
1012
with peak
no peak
Protons
Sn_IIn(Emax=4x150 PeV)
Sn_Ia (Emax=4 PeV)
F=E-2.2 (1 +(E/Ek))c/
F(E
) E
2.2
E, GeV
Mass composition in 3-d variantcoincides with Tunka -133 last data
Mass composition: 3 dif. variants• 1) Emax (P)In Galaxy ; 4 PeV
• 2) Emax (P)=4 and 600 PeVThis variant predicts a
heavy composition at 1018 eV
•3) SNR Ia + He stars
+MetaGalactic with
mixed composition in
sources
Implications of the cosmic ray spectrum for themass composition at the highest energies
D. Allard1, N. G. Busca1, G. Decerprit1, A. V. Olinto1;2, E.Parizot1
Figure 3. Propagated spectra obtained assuming a mixed source compositioncompared to HiRes (left) and Auger (right) spectra, the dierent components aredisplayed .
Variant with Meta-galactic with mixed composition and with
He-stars (without heavy nuclei) instead of SNIIn
104 105 106 107 108 109 1010 1011 1012105
106
107
FeHe
P
Metagalactika, mixed composition
Galactica: SN Ia accelerate all nuclei to 4 PeV, SN IIn to 600 PeV, butonly P, He (He stars).
F(E
) E3
.0
E, GeV
Tun133 GrandeKas Hires1 Hires2 EASTOP Tibet KASKADE Tunka25 MGUIE3 AKENO Augergv Hires1M3
Amplitude and Right ascensionof anisotropy around the knee
102 103 104 105 106 107 108 109 1010
10-4
10-3
10-2
10-1
Ani
sotr
opy
ampl
itude
E, GeV
Compilation [9] Akeno, Yakutsk , KaskadeGrande KASCADEAUGER AGASA
102 103 104 105 106 107 108 109 1010-15
-10
-5
0
5
10
15
Vela Jun 0.3 kpc 700 y
Akeno []
Calculation Vela J un Main1 Main 2
Rig
ht A
scen
sion
, hou
rs
Energy, GeV
Conclusions about Fe-peak• To get in our calculations Fe-peak we need to introduce some bump
in source spectrum with a width 0.3 or 0.1 of the order. Single nearby source could not help in this problem.
• First a very impressive fact – a very good coincidence of positions of the Fe peak and position of P-He main knee at the suggestion of normal composition.
• In the case of narrow peak (1/10 of order) Fe peak is reproduced perfectly , but the main knee should be visible as two knees. May be if we take into account an accuracy of energy and mass determination, it helps to smooth these peaks.
• The nature of the bump in a source spectrum is not clear fully. But it can reflect the time dependent emissions – most energetic particles are emitted at the beginning of the acceleration process, when the speed of shock wave is maximal. This bump should be seen during 104 ears (time of collecting of PeV signal from the sources due to propagation) and should be variable in the time .
Propagation Time for different energies
103 104 105 1061E-4
1E-3
0,01
0,1
1
protons R=1 kpcF
E3
Age of SNR (years)
100 GeV 1 TeV 10 TeV 100 TeV 1PeV
We can identified
Всего 25 с R <1.5 кпс и T <105 лет (всего 73 до 3 кпс)
Чистые SNR 6 (без пульсаров, похожие на сверхновые Ia (25%). В 19 есть либо PWN (11 штук) либо гамма-пульсар (11 штук),
Из 19 HESS зарегистрировал ТэВ-ное излучение только в 30 %,
Из 6 SNR - только в 1 (Только в J1713-3946) Тэвное излучение.
Используемый набор потенциальных источников КЛ.
HSWFP Lград.
DmnКпс
Tклет
Name
_SW__ 65.3 0.8 20. G65.3+5.7
_SW__ 65.7 1.5 0. DA495
_S___ 74.0 0.44 20. Cygn Loop
_S_F_ 78.2 1.5 7. DR4
_S___ 89.0 0.8 19. HB21
_S__ 93.7 1.5 120. CTB104,DA551
_SWFP 106.3 0.8 10. Boomerang
_S__P 114.3 0.7 7.7 G114.3+0.3
_SWF_ 119.5 1.4 14. CTA
_S___ 127.1 1.2 0. R5
_S___ 160.9 0.8 6.6 HB9
_SW_P 180.0 0.8 4.6 S147
_SW__ 189.1 1.5 20. IC443, 3C157
HSWFP 263.9 0.29 11.0 Vela X
HSWF_ 266.2 1.3 10. Vela Jun.
HWFP 343.1 1.4 18. FermiG343.1
HS___ 347.3 1.0 1.6 J1713-3946
H____ 353.6 0.8 27. HESSG353.6
___P 49.1 1.4 88. PSRB1916
___FP 201.1 0.29 110. Monogem
__W__ 291.0 1.0 0. PWNG291.02-0.11
___FP 201.2 0.75 44. J0631+1036
__WF__ 7.4 1.7 68. J1809-2332
H__F_ 80.2 1.6 120. J2032+4127