Multi-Messenger Astonomy with Cen A?
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1 Multi-Messenger Astonomy with Cen A? Michael Kachelrieß NTNU, Trondheim []
2 Outline of the talk 1 Introduction 2 Dawn of charged particle astronomy? Expectations vs. Auger data Effects of cluster fields 3 Multi-messenger astronomy with Cen A? 4 Conclusions
3 Outline of the talk 1 Introduction 2 Dawn of charged particle astronomy? Expectations vs. Auger data Effects of cluster fields 3 Multi-messenger astronomy with Cen A? 4 Conclusions
4 Outline of the talk 1 Introduction 2 Dawn of charged particle astronomy? Expectations vs. Auger data Effects of cluster fields 3 Multi-messenger astronomy with Cen A? 4 Conclusions
5 Outline of the talk 1 Introduction 2 Dawn of charged particle astronomy? Expectations vs. Auger data Effects of cluster fields 3 Multi-messenger astronomy with Cen A? 4 Conclusions
6 1910: Father Wulf measures ionizing radiation in Paris 80m: flux/2
7 1910: Father Wulf measures ionizing radiation in Paris 300m: flux/2 80m: flux/2
8 What do we know 98 years later? solar modulation LHC
9 What do we know 98 years later? solar modulation only two bits of information? exponent α of dn/de 1/E α chemical composition, uncertain at UHE LHC
10 PAO data: energy spectrum
11 PAO data: energy spectrum )) -1 s -1 sr -1 ev -2 lg(j/(m E (ev) ) J/(AxE Auger HiRes I lg(e/ev)
12 PAO data: energy spectrum )) -1 s -1 sr -1 ev -2 lg(j/(m E (ev) E 1/2 consistent with GZK suppression 1 ) J/(AxE Auger HiRes I lg(e/ev)
13 PAO data: chemical composition ] 2 <X max > [g/cm 850 Auger ICRC proton iron QGSJETII-03 QGSJET01 SIBYLL2.1 EPOS E [ev]
14 PAO data: chemical composition ] 2 <X max > [g/cm 850 Auger ICRC proton iron QGSJETII-03 QGSJET01 SIBYLL2.1 EPOS E [ev] limits strongly all top-down or Z burst models
15 PAO data: chemical composition ] 2 <X max > [g/cm 850 Auger ICRC proton iron QGSJETII-03 QGSJET01 SIBYLL2.1 EPOS E [ev] limits strongly all top-down or Z burst models points to heavier composition at UHE
16 PAO data: chemical composition ] 2 <X max > [g/cm 850 Auger ICRC proton iron QGSJETII-03 QGSJET01 SIBYLL2.1 EPOS E [ev] limits strongly all top-down or Z burst models points to heavier composition at UHE supported by fluctuations of X max
17 What is the bonus of UHECR astronomy? astronomy with VHE photons restricted to few Mpc: 22 radio log10(e/ev) 16 photon horizon γγ e + e CMB 14 IR kpc GC 10kpc 100kpc Mpc Virgo 10Mpc 100Mpc Gpc
18 What is the bonus of UHECR astronomy? astronomy with VHE photons restricted to few Mpc: astronomy with HE neutrinos: large λ ν, but also large uncertainty δϑ > 1
19 What is the bonus of UHECR astronomy? astronomy with VHE photons restricted to few Mpc: astronomy with HE neutrinos: large λ ν, but also large uncertainty δϑ > 1 small event numbers: < few/yr for PAO or ICECUBE identification of steady sources challenging
20 What is the bonus of UHECR astronomy? proton horizon 18 log10(e/ev) 16 photon horizon γγ e + e CMB 14 IR kpc GC 10kpc 100kpc Mpc Virgo 10Mpc 100Mpc Gpc
21 What is the bonus of UHECR astronomy? proton horizon 18 log10(e/ev) kpc photon horizon γγ e + e use larger statistics of UHECRs well-suited horizon scale small enough deflections in magnetic fields? GC Virgo 10kpc 100kpc Mpc 10Mpc 100Mpc CMB IR Gpc
22 Energy losses, the dip and the GZK cutoff 1e-07 1e-08 (1/E)*dE/dt [1/yr] 1e-09 pion production pair production 1e-10 redshift 1e log10(e/ev) at E ev: N + γ 3K N + π starts and reduces free mean path to 20 Mpc pair production leads to a dip at ev
23 Possible anisotropies of extragalactic CRs: 1 Dipole anisotropy cosmolog. Compton-Getting effect induced by motion of Sun relative to cosmological rest frame requires λ CR (E) > λ LSS
24 Possible anisotropies of extragalactic CRs: 1 Dipole anisotropy cosmolog. Compton-Getting effect induced by motion of Sun relative to cosmological rest frame requires λ CR (E) > λ LSS 2 Anisotropies on medium scales z 0.2: spots with l degrees reflects LSS of matter, modified by B requires λ CR (E) < few λ LSS
25 Possible anisotropies of extragalactic CRs: 1 Dipole anisotropy cosmolog. Compton-Getting effect induced by motion of Sun relative to cosmological rest frame requires λ CR (E) > λ LSS 2 Anisotropies on medium scales z 0.2: spots with l degrees reflects LSS of matter, modified by B requires λ CR (E) < few λ LSS 3 Small-scale clustering Small-scale angular resolution of experiments CR from the same (?) point sources requires small qb/e and small N s
26 Possible anisotropies of extragalactic CRs: 1 Dipole anisotropy cosmolog. Compton-Getting effect induced by motion of Sun relative to cosmological rest frame requires λ CR (E) > λ LSS 2 Anisotropies on medium scales z 0.2: spots with l degrees reflects LSS of matter, modified by B requires λ CR (E) < few λ LSS 3 Small-scale clustering Small-scale angular resolution of experiments CR from the same (?) point sources requires small qb/e and small N s 4 Correlations with specific sources requires small qb/e and small N s
27 Correlations with AGNs: Auger analysis AGN from VCC catalogue:
28 Correlations with AGNs: Auger analysis first data set with data < May 2006 to fix cuts: E th = 56EeV, l 0 = 3.1 and d 75Mpc.
29 Correlations with AGNs: Auger analysis first data set with data < May 2006 to fix cuts: E th = 56EeV, l 0 = 3.1 and d 75Mpc. second data set May 2006 August 2007: 13 events, 8 correlated, 2.7 expected p ch
30 Correlations with AGNs: Auger analysis first data set with data < May 2006 to fix cuts: E th = 56EeV, l 0 = 3.1 and d 75Mpc. second data set May 2006 August 2007: 13 events, 8 correlated, 2.7 expected p ch just a 3 σ effect, test against isotropy, no propagation
31 Correlations with AGNs: Auger analysis first data set with data < May 2006 to fix cuts: E th = 56EeV, l 0 = 3.1 and d 75Mpc. second data set May 2006 August 2007: 13 events, 8 correlated, 2.7 expected p ch just a 3 σ effect, test against isotropy, no propagation AGN or something with similar distribution?
32 Correlations with AGNs: PAO analysis 27 CRs ( ) and 472 AGN ( ):
33 Correlations with AGNs: PAO analysis 27 CRs ( ) and 472 AGN ( ): Virgo does not contribute [Gorbunov et al. 08 ]
34 Energy threshold consistent with GZK horizon? 8 out of 13 CRs (E 57EeV) correlated within 75 Mpc: % 30 % 50 % 70 % 90 % 100 R [Mpc] e+19 1e+20 1e+21 E [ev]
35 Energy threshold consistent with GZK horizon? 8 out of 13 CRs (E 57EeV) correlated within 75 Mpc: % 30 % 50 % 70 % 90 % 100 R [Mpc] e+19 1e+20 1e+21 E [ev]
36 Energy threshold consistent with GZK horizon? 8 out of 13 CRs (E 57EeV) correlated within 75 Mpc: % 30 % 50 % 70 % 90 % 100 R [Mpc] 10 under-estimation of energy scale? or iron? or fake? 1 1e+19 1e+20 1e+21 E [ev]
37 Energy threshold consistent with GZK horizon? 8 out of 13 CRs (E 57EeV) correlated within 75 Mpc: % 30 % 50 % 70 % 90 % 100 R [Mpc] 10 under-estimation of energy scale? or iron? or fake? safer (but less ambitious) method? 1 1e+19 1e+20 1e+21 E [ev]
38 Comparing with sources: [A. Cuoco et al. 07, 08 ] Use the auto-correlation function, w(ϑ) = DD(ϑ) RR(ϑ) 1, where DD: number of pairs in catalogue RR: number of pairs in random sets for most popular sources of UHECRs:
39 Comparing with sources: [A. Cuoco et al. 07, 08 ] Use the auto-correlation function, w(ϑ) = DD(ϑ) RR(ϑ) 1, for most popular sources of UHECRs: AGN
40 Comparing with sources: [A. Cuoco et al. 07, 08 ] Use the auto-correlation function, w(ϑ) = DD(ϑ) RR(ϑ) 1, for most popular sources of UHECRs: AGN and GRB [ ]
41 Auto-correlation function of different sources: [A. Cuoco et al. 07 ]
42 Auto-correlation function of different sources: [A. Cuoco et al. 07 ]
43 Auto-correlation function of different sources: [A. Cuoco et al. 07 ]
44 Auto-correlation function of different sources: [A. Cuoco et al. 07 ] differences on all angular scales reduced statistical error reduced dependence on B: global comparison on all scales only relative deflections enter possible to constrain B
45 Auto-correlation function of different sources: [A. Cuoco et al. 07 ] differences on all angular scales reduced statistical error reduced dependence on B: global comparison on all scales only relative deflections enter possible to constrain B
46 Auto-correlation function of different sources: [A. Cuoco et al. 07 ] differences on all angular scales reduced statistical error reduced dependence on B: global comparison on all scales only relative deflections enter possible to constrain B
47 Auto-correlation function of different sources: [A. Cuoco et al. 07 ] differences on all angular scales reduced statistical error reduced dependence on B: global comparison on all scales only relative deflections enter possible to constrain B
48 Clustering signal for the PAO Science data [A. Cuoco et al. 08 ]
49 Clustering signal for the PAO Science data [A. Cuoco et al. 08 ] larger consistency of data with AGN than normal galaxies only consistency check, no independent evidence bad cross-correlation of old data [A. Cuoco et al. 07 ]
50 Effects of cluster fields [K. Dolag, MK, D. Semikoz 08 ] Sources sit in regions with ρ ρ and B B
51 Effects of cluster fields [K. Dolag, MK, D. Semikoz 08 ] Sources sit in regions with ρ ρ and B B what are effects of cluster fields?
52 Anisotropies of a single source at 1000 EeV/Z model z 1000 EeV
53 Anisotropies of a single source at 100 EeV/Z model z 100 EeV
54 Anisotropies of a single source at 10 EeV/Z model z 10 EeV
55 Anisotropies of a single source at 1 EeV/Z model z 1 EeV
56 Effects of cluster fields: [K. Dolag, MK, D. Semikoz 08 ] anisotropies hide cluster for part of observer 1 2 less 2 more 5 less P(δ) E [EeV]
57 Effects of cluster fields: [K. Dolag, MK, D. Semikoz 08 ] anisotropies hide cluster for part of observer modulate the energy spectrum 10 1 fit 1/E 2.2 no MF (0,0) (40,-10) (90,45) dn/de E [EeV]
58 Multi-Messenger Astronomy with Cen A? [] MK, S. Ostapchenko, R. Tomàs 08
59 Possible source/acceleration scenarios for Cen A: mechanism: shock acceleration vs. acceleration in regular fields location: core, hot spots, along the jet target: gas vs. photons
60 Possible source/acceleration scenarios for Cen A: mechanism: shock acceleration vs. acceleration in regular fields location: core, hot spots, along the jet target: gas vs. photons
61 Possible source/acceleration scenarios for Cen A: mechanism: shock acceleration vs. acceleration in regular fields location: core, hot spots, along the jet target: gas vs. photons
62 Possible source/acceleration scenarios for Cen A: mechanism: shock acceleration vs. acceleration in regular fields location: core, hot spots, along the jet target: gas vs. photons neglect acceleration fix 2 basic scenarios: core and jet fix n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis
63 Chandra observation of X-ray emission in the jet 1 arcmin
64 Chandra observation of X-ray emission in the jet divide in subareas separate fit to gas column density X and spectral index α
65 Chandra observation of X-ray emission in the jet: Results 1 arcmin X = /cm 2 in the jet
66 Chandra observation of X-ray emission in the jet: Results 1 arcmin X = /cm 2 in the jet with d = 0.4kpc and σ pp = 150mbarn: interaction depth τ pp 0.01
67 Length scales for acceleration in the jet
68 Length scales for acceleration in the jet diffusion increases effective size
69 Length scales for acceleration in the jet diffusion increases effective size for pp no threshold τ = 1 for E = ev, optimal for neutrino telescope
70 Our two base models acceleration close to the core acceleration in accretion shock/regular fields pγ interactions τ γγ 1, synchrotron losses for e ± acceleration in jet shock acceleration pp interactions τ γγ 1, synchrotron losses for e ±
71 Results for acceleration in jet: broken power-law
72 Results for acceleration in jet: broken power-law
73 Results for acceleration in jet: broken power-law source with τ 1 visible in TeV range τ pp τ γγ
74 Results for acceleration in jet: broken power-law α = 2.7 required for diffuse CR flux in dip model disfavoured as spectrum of single source Cen A diffuse spectrum = superposition of single sources with dn/de max distribution HE γ observations constrain UHECR models
75 Results for acceleration in jet: α = 2
76 Results for acceleration in jet: α = 1.2
77 Results for acceleration close to the core: broken power-law
78 Results for acceleration close to the core: broken power-law source with τ pγ 1 (weakly) visible in TeV range UHE photons are reshuffled
79 Results for acceleration close to the core: broken power-law
80 Results for acceleration close to the core: α = 2
81 Results for acceleration close to the core: α = 1.2
82 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis
83 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis HE neutrino astronomy: exploiting directional signal (=muons) requires northern experiment event number most sensitive on steepness of CR spectrum: 10 4 few events per year
84 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis HE neutrino astronomy: exploiting directional signal (=muons) requires northern experiment event number most sensitive on steepness of CR spectrum: 10 4 few events per year if typical steady source, first detection of diffuse flux [Koers, Tinyakov 08 ]
85 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis HE neutrino astronomy: exploiting directional signal (=muons) requires northern experiment event number most sensitive on steepness of CR spectrum: 10 4 few events per year if typical steady source, first detection of diffuse flux HE gamma astronomy: all cases promising apart from α 1 [Koers, Tinyakov 08 ]
86 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis HE neutrino astronomy: exploiting directional signal (=muons) requires northern experiment event number most sensitive on steepness of CR spectrum: 10 4 few events per year if typical steady source, first detection of diffuse flux HE gamma astronomy: all cases promising apart from α 1 general: TeV photon sources may be also good neutrino sources [Koers, Tinyakov 08 ]
87 Summary Cen A fixed n γ and n H by observations normalization of UHECRs by PAO AGN hypothesis HE neutrino astronomy: exploiting directional signal (=muons) requires northern experiment event number most sensitive on steepness of CR spectrum: 10 4 few events per year if typical steady source, first detection of diffuse flux HE gamma astronomy: all cases promising apart from α 1 general: TeV photon sources may be also good neutrino sources pp may be more important than pγ in jet [Koers, Tinyakov 08 ]
88 General summary tension between horizon and fraction of correlated PAO events
89 General summary tension between horizon and fraction of correlated PAO events tension between chemical composition and correlation data from PAO
90 General summary tension between horizon and fraction of correlated PAO events tension between chemical composition and correlation data from PAO nuclei with admixture of protons?
91 General summary tension between horizon and fraction of correlated PAO events tension between chemical composition and correlation data from PAO nuclei with admixture of protons? auto-correlation more robust method than cross-correlation
92 General summary tension between horizon and fraction of correlated PAO events tension between chemical composition and correlation data from PAO nuclei with admixture of protons? auto-correlation more robust method than cross-correlation lensing in cluster and Galactic fields important
93 General summary tension between horizon and fraction of correlated PAO events tension between chemical composition and correlation data from PAO nuclei with admixture of protons? auto-correlation more robust method than cross-correlation lensing in cluster and Galactic fields important connection to TeV γ-rays, acceleration
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