Upload
elaine-wade
View
31
Download
0
Tags:
Embed Size (px)
DESCRIPTION
First galaxies and reionization of the Universe: current status and problems. A. Doroshkevich Astro-Space Center, FIAN, Moscow. Theoretical expectations and observational problems. Scientific activity: >17 publications in 2012 - PowerPoint PPT Presentation
Citation preview
First galaxies and reionization of the Universe:
current status and problems
A. Doroshkevich
Astro-Space Center, FIAN, Moscow.
Theoretical expectations and observational problems
• Scientific activity: >17 publications in 2012• z~25 – 10 - formation of the first stars
• and ionizing bubbles • Bubble model, UV-background,
• non homogeneities in xH and Tg
• z~ 10 WMAP: τT~0.1, xH=nH/nb << 1
• z~6.5 – 5 - high ionization, xH~10-3
• z< 3 - xH~10-5
• 1. We do not see any manifestations of the first stars• 2. We do not know the main sources of ionizing UV
radiation
Universe Today 12.12.2012
Possible sources of ionizing UV background
1. exotic sources – antimatter, unstable particles, etc…
2. First stars Pop III with Zmet<10-5 Z¤ or
3. non thermal sources - AGNs and Black Holes
4. Quasars at z < 3.5, He III
Reionisation• Θ(z)=α(T)n(z)H(z)~3T4
-0.7z103/2, T4~2.
• For z10>1 recombination becomes important !
Thermal sources: E~7MeV/baryon, Nγ< 5 105 /baryon Non thermal sources - AGNs and Black Hole
E~ 50MeV/baryon, Nγ~3.5 106 /baryon
Ωmet~2 10-6Ωbar~8 10-8, Ωbh~3 10-7Ωbar~ 10-8
In reality both sources are important.
• fesc~ 0.1 - 0.02, Nbγ~1 - 204.0
105108.0
5
7 b
esc
b
esc
bbrei Nf
N
Nf
N
Labbe I., 2010,ApJ.,708,L26, 1209.3037
• Spitzer photometry• Z~8, 63 candidats,• 20 actually detected
• SMD for M<-18
• ρ*(z=8)~106Ms/Mpc3
• Ω*(z=8)~0.4 10-5
• Ωmet(z=8)~0.4 10-7
• Ωreio~10-7 – 10-8
z~2.5, Ωmet~2.3 10-6 for IGM,
Ωmet~3 10-5 for galaxies
Universe Today 1211.6804
Ellis et al. arXiv1211.6804
Three steps of galaxy formation
• 1. Formation of the virialized relaxed massive DM • cloud (perhaps, anisotropic) at z<zrec~103 with• ρcl ~200<ρ(z)> and overdensity δDM~104 z10
7M91/2
• 2. Cooling and dissipative compression of the baryonic• component, but the bulk motions and the kinetic • temperature of stars are preserved• 3. Formation of stars – luminous matter with M>MJ
• Main Problem of the star formation• MJ/M¤~2·107T4
3/2nb-1/2,
• For stars: T4~10-2, nb>102cm-3 , MJ/M¤<103
• z=zrec,T4~0.3, nb~250 cm-3, MJ/M¤ ~2·105
• Parameters of baryonic components• <ρbar>~4·10-28z10
3g/cm3, <ρgal>~10-24g/cm3,• <ρstar>~1 g/cm3, ρBH~2 M8
-2g/cm3
• Cooling factors: H2 molecules and metals (dust, C I etc.)•
Simulations (2001)• The box ~1Mpc, 128 -256 cells,
• Ndm~107, mdm~30M0, Mgal~106 – 107 M0
• Very useful general presentation
• (the galaxy and star formation are possible)
• Restrictions:
• a. small box → random regions (void or wall) & unknown small representativity
• b. large mass DM particles in comparison with the mass of stars.
What is mostly interesting
• a. realization – it is possible!
• b. wide statistics of objects -- what is possible for various redshifts
• c. rough characteristics of internal structure of the first galaxies
• d. general quantitative analysis of main physical processes
Density – temperature 2001
Machacek et el. 2001, ApJ, 548, 509
• M~5 105Ms
• T4~0.3• nb~10cm-3
• fH2~3 10-5
• j21~1• MJ(25)~104Ms
• MJ(20)~500Ms
• Lazy evolution, • Monolitic object• Monotonic growth
ρ(z)??? Instabilities!
ρ, T & Z, Wise 1011.2632
• Formation of massive galaxies owing to the merging of low mass galaxies.
Influence of the LW background
• Actual limit is JLW21~1 – 0.1 for various redshifts
• For the period of full ionization z~10 we get
• JLW 21~4 Nbγ
• This means that at at 10>z>8.5
• the H2 molecules are practically destroyed and star formation is strongly suppressed
• This background is mainly disappeared at z~8.5
Safranek-Shrader, 1205.3835
• Corrections• for both limits• ~10 times
• J21~4Nbγ
UV-background from BH accretion
• T4~1 – 4, for sources with Eg~10eV and Eg~50eV. and depends upon cooling factors (radiative and expansion)
Elvert:
• In the case we can use
44 /)74(4 103.6 TT
HI
e TNN
New semi analytical approach We know the process of the DM halo formation
and can use this information
• Assumptions:
• a. what is the moment of halo formation
• b. baryons follow to DM and have the same
• pressure and kinetic temperature
• c. what is the cooling of the baryonic
• components
• d. thermal instability leads to formation of
• stars with masses Mst > MJeans
Physical model• Two steps of the DM halo formation• We consider the homogeneous ball with mass
• M=109Mo M9
• within the expanded Universe. Its evolution can • be described analytically up to the collapse at
• 1+z=10zf
• and subsequent relaxation. In the case we have • for the NFW profiles two parametric description:
• ρDM~10-23g/cm3M91/2zf
10,
• TDM~40eV M95/6zf
10/3mDM/mb
• and all other characteristics.
Analytical characteristics for DM component
• For the NFW halo with the virial
• mass M=109 M9 Ms formed at zf=(1+z)/10
• Within central core with r< rs we have
• ρDM~10-23g/cm3M91/2zf
10, TDM~40eV M95/6zf
10/3mDM/mb
• Cooling factors: H2 and atomic for T4>1,
• Three regimes of the gas evolution – • slack, rapid and isothermal• Thermal instability and the core formation
• Stars are formed for Tbar<100K and nbar>100cm-3
• with Mstar > MJ ~5 107T43/2/nbar
1/2Ms
Formation of the first stars with Mcl/M0 = 3 105 and 7 105, zf=24 (left)
and Mcl/M0=0.7 108 and 3 108, zf=11 (right)
Low mass limit for the rapid-lazy formation of the first galaies
Behroozi et al., 1207.6105 Stellar mass vs. host halosSmall fraction of stars
Behroozi et al., 1209.3013 - SFR(Mh)
• SMF~Mh-4/3, M>Mch; SMF~Mh
2/3, M<Mch (left panel)
• Ms/Mh<2 – 3% at all z! ?continual evolution?
comments• Stars occupy very small matter fraction ?• Low massive objects dominate at all redshifts? • Is this impact of nature or selection effect?• Formation of the massive galaxies owing to the • merging of satellites with stars?? • Illingworth 1977 for 13 E-galaxies• Fraction of massive objects increases more rapidly –
merging of satellites or other factors??• Small scale perturbations and missing satellite
problem – when and where had been formed dwarf galaxies.
Physical model
• ρDM~10-23g/cm3M91/2zf
10,
• TDM~40eV M95/6zf
10/3mDM/mb
• rs=2.3M131/6/zf
10/3kpc=0.16M61/6/zf
10/3kpc
• Zf=0.55σv0.1/rs
1/4≈0.27M13-0.1≈1.33M6
-0.1
• Problems of the measurements – T(r) and • dynamical masses, finally:
• rs~M61/2, T~M6
1/2
10 clusters of galaxies Pointecouteau et al., A&A,435, 1, 2005 ,Pratt et al., A&A 446,429 name z R +/- T +/- M13 +/- M/TR 1+z Mpc keV 10^13M_o A1983 0.0442 0.717 0.110 2.2 0.1 10.90 0.34 0.95E+00 2.05 A2717 0.0498 0.668 0.076 2.6 0.1 8.80 0.23 0.70E+00 2.27 MKW9 0.0382 0.717 0.036 2.4 0.2 11.00 0.11 0.86E+00 2.11 A1991 0.0586 0.737 0.034 2.7 0.1 12.00 0.10 0.82E+00 2.13 A2597 0.0852 0.897 0.032 3.7 0.1 22.20 0.10 0.92E+00 2.00 A1068 0.1375 1.060 0.025 4.7 0.1 38.70 0.07 0.11E+01 1.88 A1413 0.1430 1.129 0.029 6.6 0.1 48.20 0.09 0.88E+00 1.97 A478 0.0881 1.348 0.047 7.1 0.1 75.70 0.15 0.11E+01 1.79 PKS 0745 0.1028 1.323 0.034 8.0 0.3 72.70 0.10 0.94E+00 1.88 A2204 0.1523 1.365 0.032 8.3 0.2 83.90 0.10 0.10E+01 1.83 mns 0.92E+00 sig 0.11E+00
name sig_v +/- Mhalf +/- <rho> +/- M*zf^10 z_f +/- km/s 10^6M_o M_o/pc^3 Carina 6.60 1.20 3.40 1.40 0.320 0.120 0.18 0.12E01 0.53Draco 9.10 1.20 11.00 3.00 0.230 0.060 0.23 0.11E01 0.32Fornax 11.70 0.90 27.00 0.50 0.160 0.030 0.25 0.99E00 0.04LeoI 9.20 1.40 6.50 2.10 0.660 0.210 0.50 0.12E01 0.44LeoII 6.60 0.70 3.10 0.90 0.400 0.120 0.21 0.12E01 0.39Sculptor 9.20 1.10 4.60 1.70 1.300 0.500 0.83 0.13E01 0.55Sextant 7.90 1.30 11.00 4.00 0.100 0.030 0.99 0.99E00 0.39UMi 9.50 1.20 7.80 2.20 0.550 0.150 0.46 0.12E01 0.37CVen I 7.60 0.40 19.00 2.00 0.025 0.003 0.32 0.84E00 0.10Coma 4.60 0.80 0.90 0.35 0.490 0.180 0.14 0.13E01 0.56Hercules 3.70 0.90 2.60 1.40 0.017 0.009 0.82 0.89E00 0.53 Leo T 7.50 1.60 5.80 2.80 0.250 0.120 0.18 0.11E01 0.59Segue 1 4.30 1.20 0.31 0.19 3.010 0.800 0.50 0.17E01 1.06UMa I 11.90 3.50 26.10 6.00 0.200 0.120 0.30 0.10E01 0.29UMa II 5.70 1.40 2.60 1.40 0.230 0.120 0.11 0.12E01 0.68AndII 9.30 2.70 62.00 36.00 0.008 0.005 0.19 0.71E01 0.45Cetus 17.00 2.00 99.00 23.00 0.110 0.020 0.32 0.90E00 0.22Sgr^c 11.40 0.70 120.00 60.00 0.008 0.001 0.24 0.68E00 0.35Tucana 15.80 3.60 40.00 19.00 0.460 0.220 0.86E 0.11E01 0.57Bootes 1 6.50 2.00 5.90 3.70 0.100 0.060 0.73E 0.10E01 0.70Cven II 4.60 1.00 0.90 0.40 0.530 0.250 0.15E 0.13E01 0.65Leo IV 3.30 1.70 0.73 0.73 0.110 0.110 0.28E 0.11E01 1.26Leo V 2.40 1.90 0.14 0.14 0.450 0.450 0.51E 0.14E01 1.57Segue 2 3.40 1.80 0.23 0.23 1.310 0.300 0.19E 0.16E01 1.59AndIX 6.80 2.50 14.00 11.00 0.023 0.017 0.26E 0.84E00 0.73AndXV 11.00 6.00 19.00 2.00 0.230 0.250 0.30E 0.10E01 0.22mns 0.23Esig 0.23E
Walker et. al, 2009, ApJ, 704, 1274 - 28 objects
zf & zfM60.1 for 28 dSph galaxies
The endThe end
• Behroosi et al. 1209.3013
Comments
• Importance – instead of the experiment
• Complexity, representativity and precision (WMAP).
• Modern facilities
• Our attempts – simulations versus analysis
Cooling functions.
Smith, B.,2008, MNRAS, 385, 1443
SN explosions
• W=GM2/Rvir~3·1055z10M95/3erg
• ESN~1052 – 1055 erg
• Dex<0.2 – 0.5 Mpc - IGM impact
• For M9>0.1 we have SN metal enrichment • within galaxy, otherwise – matter ejection• Low massive stars, satellites and merging
Bradley L., 1204.3641, UV luminosity function for z~8
• Low massive
objects dominate
• Why?• Is this selection
effect?• What about object
collections? suppression of object formation ?
• What is at z=9? 10?
Tollerud et al. 2008, ApJ, 688, 277
• Observations of the Milky Way satellites with different corrections
16 observed dSph galaxies (Walker et al.2009)dominated by DM component
• DM parameters
• ρ~0.07M61/2f3(M6)
• P~37f4(M6)
• S~14M60.83/f(M6)
• Z10=0.9M6-0.1
• Bovill & Ricotti,• 2009, ApJ, 693,1859• Tollerud et al. 2008
Conclusions
• We do not see any manifestations of
the first stars• We do not know the main sources of ionizing
UV radiation • A. It seems that first stars Pop II & III , SNs, GRBs
are approximately effective (~30 – 40%)• B. non thermal sources BHs remnants and/or
AGNs are more effective (~50% + ?)• C. We can semi analytically describe the formation
and evolution of the first galaxies
Galaxies and BHs
BHs are observed in~1% of all galaxies, n~10-4Mpc-3
• Very massive BHs are observed as QSRs with • Nqsr~10-5 – 10-6 Mpc-3 at z<5; mainly at z~2 – 2.5
• Perhaps, there are AGNs in 70% of old massive galaxies.
• ρBH~3 10-2M9-2g/cm3,
• ρDM~10-23zf10M9
0.5g/cm3 within halo
Vestergaard et al. 2008
BH-distributions: M(z) & L/Led
Vestergaard, Osmer, 2009, ApJ,699,800
Number density of the SMBH,Kelly et al., 2011, 1006.3561
BH evolution
• 1. We see rare supermassive BH at z<2 • - early formation and short lifetime.• 2. Impact of the accretion rate. • 3. Are the SMBH primordial? • 4. van den Bosch, Nature, arXiv:1211.6429• NGC 1277, M~1.2 1011M, MBH~1.7 1010M
• 5. Nature: Simcoe et al., 2012,• QSR ULASJ120+064, z=7.08, Zmet< 10-4Z
SMBH formation
• Accretion of baryons from a thin/thick or HMD disk, major or minor mergers,
from Pop III BH remnants (Shapiro 2005).
• Problems: small mass of remnants (<103M)
• For the observed SMBHs MBH~(105 – 1010)M
• The expected mass amplification is (103 – 104).
• Primordial BH (Ricotti et al. 2007, Duching 2008)
Three scenario of the BH formation
Simplest problem – first galaxies and POP III stars • Two processes of the H2 formation
• H+e=H-+γ, H-+H=H2+e, γ~1.6eV
• H+p=H2+ +γ, H2
++H=H2+p
• Epar=128K, Eort=512K
• In both case the reaction rate and the H2 concentrations are proportional to <ne>=<np>
• At 1000>z>zrei xe=ne/<n>~10-3 what is very small value.
• Feedback of LW radiation 912A<λ<1216A
• H2+γLW =2H
Redshift variations of intensity of the UV
background
SMGs, Yun et al., 1109.6286
Gonzalez V., 2011, ApJ, 735, L34
Observed galaxies and IGMΩmet as the cumulative measure
z~10 Ωreio >(1 – 8)10-8
• z~0, Ωmet~5.7 10-4
• z~2.5 Ωmet~3. 10-5 for galaxies with Mstar>109Mo
• z~7, Ωstar~4 10-6, • Ωmet~10-2Ωstar~4 10-8
• Possible explanations : • a. Low massive galaxies ?, b. non thermal sources
c. strong non homogeneity (bubbles)
UV luminosity densityOesch P., 2012, ApJ.745, 110
MJ , Bromm et al., 1102.4638
XXXXXX OBSERVATIONS• 5-year WMAP data:
• τe=0.087±0.017, zrec=10.8±1.4
• However: Pol~ΔT2τe, and ΔT2(DV)=2ΔT2(WMAP)
• Therefore, τe<0.9 and zrec<10.8
• BUT
• Quasars and galaxies are seen at z~8 - 9
• τe~0.04 – 0.05, z~7
• τe~Δτe~0.001 – 0.06, 7< z <1000
• One object at z~9.5,
Observed galaxies and IGMΩmet as the cumulative measure
• We like to have at least
• fesc~0.1 – 0.01, Nbp>1, Nph~5 105
• Ωmin=ΩbNbp(fescNph)-1~10-7(Nbp/fesc)(Ωb/0.04)• -----------------------------------------------------------------------------------------------------------------
• z~2.5, Ωmet~3 10-5 for galaxies,
• z~2.5, Ωmet~2.3 10-6 for IGM,• --------------------------------------------------------------------------------------------------------------------------------------
• z~5, Zmet=0.1Z~2 10-3,
• Ω*~6.7 10-5, Ωmet=Ω*Zmet~ 1.3 10-7 for galaxies
• ΩC~(5±1.7) 10-8, z<5.5, ΩC~(4.5±2.6) 10-9, z>5.5,