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High-Energy Cosmic Particles by Black-hole Jets in Galaxy Clusters
Ke Fang Einstein Fellow, Stanford University
YITP Workshop, Kyoto, Japan (virtual attendance) Dec 10, 2020
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• A “common origin” of cosmic particles?
• Cosmic-ray acceleration and confinement
• Astroparticles from galaxy clusters
3
• A “common origin” of cosmic particles?
• Cosmic-ray acceleration and confinement
• Astroparticles from galaxy clusters
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UHECRs, High-energy Neutrinos & Gamma Rays
Ultrahigh Energy Cosmic Ray (UHECR)
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Ultrahigh Energy Cosmic Ray (UHECR)
Telescope Array, ICRC (2015)
UHECRs, High-energy Neutrinos & Gamma Rays
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Light component in the transition
regimeKASCADE, LOFAR,
IceTop
KASCADE-Grande (ICRC 2017)
UHECRs, High-energy Neutrinos & Gamma Rays
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TeV - PeV: Detected by IceCube since 2013
UHECRs, High-energy Neutrinos & Gamma Rays
1010 1012 1014 1016 1018 1020
Emax [eV]
1042
1043
1044
1045
1046
1047
E opt[e
rgM
pc°
3yr
°1 ]
novae
SLSNe-I
SLSNe-II
SN-IIn
CCSNeTDE
FBOT
Luminous FBOTIa-CSM
≤rel <1%
≤rel <100%
E∫ > 100 TeV
IceCube DiÆuse Neutrinos
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Neutrino Sources are Powerful and Abundant!
KF, Metzger, Vurm, Aydi, Chomiuk (2020)
Transients powered by non-relativistic shocks can barely explain the IceCube diffuse neutrinos.
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~14% of the Fermi extragalactic gamma-ray background is contributed by unknown sources. Fermi Collabora,on (2016)
Lisan, et al (2016)
UHECRs, High-energy Neutrino & Gamma Rays
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When putting them together..
Despite ten orders of magnitudes difference in energy, UHECRs, IceCube neutrinos, Fermi non-blazar EGB share similar energy injection rate.
Murase, Ahlers & Lacki (2013), Waxman 1312.0558, Giacin, et al (2015), Murase & Waxman (2016), Wang & Loeb (2017) …
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A common origin is nontrivialThe sources need to provide the right
interaction probability
Truncation / hard spectrum below ~TeV
[e.g., Murase, Guetta & Ahlers, (2016), Bechtol+ (2017)] Neutrinos above 10 PeV?
[IceCube Coll. (2018)]
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• A “common origin” of cosmic particles?
• Cosmic-ray acceleration and confinement
• Astroparticles from galaxy clusters
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• “Mini AGN” in our own galaxy with extended X-ray jets
Black Hole Jets as Cosmic Accelerators Microquasar SS 433
ROSAT 0.2 keVHAWC ~20 TeV
• TeV gamma-rays in both lobes detected by HAWC
HAWC Collaboration, Nature (2018)KF as a main author
• GeV counterparts identified in Fermi-LAT data
KF, Charles, Blandford, ApJL (2020)
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HAWC Collaboration, Nature (2018)KF as a main author
KF, Charles, Blandford, ApJL (2020)
ROSAT 0.2 keVHAWC ~20 TeV
• Electrons above 20 TeV were accelerated
• Particle acceleration sites ~30 pc away from hole
E ⇠ Z 1019✓
B
1µG
◆✓R
10 kpc
◆eV
Scaling to jets of supermassive black holes:
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Confinement of Cosmic Rays in Local Environment Cygnus Cocoon
GeV to100 TeV gamma-rays trace infrared emission
HAWC Collaboration, under reviewKF as a main author
Fermi-LAT Coll., Science (2011)
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• A “common origin” of cosmic particles?
• Cosmic-ray acceleration and confinement
• Astroparticles from galaxy clusters
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nICM(r) = nICM,0
"1 +
✓r
rc
◆2#�3�/2ICM gas
Radiation backgrounds: Infrared background from galaxies, CMB, Extragalactic background lights
Magnetic field following Kolmogorov turbulence
The Intracluster Medium Environment for Interactions
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KF & Olinto (2017)KF & Murase Nature Physics (2018)
Strength of magnetic field in the core of a galaxy cluster
CRPropa3 + SOPHIA for turbulent field & [Ba,sta+ JCAP (2016)]
EPOS for [KF, Kotera & Olinto ApJ (2012)]
Diffuse propaga@on [Kotera & Lemoine PRD (2007), KF & Olinto ApJ (2016)]
N�
Np
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Dtotal = 46Mpc
Bc = 10µG,M = 1015 M�
Particle Larmor RadiusrL = 10E19 B
�1�6 Z
�1 kpc
Field Correlation Length
l0 ⇠ 20 kpc
Particle Trajectory in the Intracluster Medium - 10 EeV
KF & Murase Nature Physics (2018)
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Bc = 10µG,M = 1015 M�
Particle Larmor Radius
rL = 0.1E17 B�1�6 Z
�1 kpc<latexit sha1_base64="1IkbeNwFzqpHyLOWl7Av/sV7vi0=">AAACGXicbVDLSgMxFM34rPU16tJNsAgu2jIRsW6EqgguXFSwD+yMQyZN29DMgyQjlGF+w42/4saFIi515d+YtrPQ1gMhJ+fcy809XsSZVJb1bczNLywuLedW8qtr6xub5tZ2Q4axILROQh6Klocl5SygdcUUp61IUOx7nDa9wcXIbz5QIVkY3KphRB0f9wLWZQQrLbmmJdxreAqtMoJ28dJNUCW1i+duUjpO75MS0o+77LaFDwcRcc2CVbbGgLMEZaQAMtRc89PuhCT2aaAIx1K2kRUpJ8FCMcJpmrdjSSNMBrhH25oG2KfSScabpXBfKx3YDYU+gYJj9XdHgn0ph76nK32s+nLaG4n/ee1YdU+chAVRrGhAJoO6MYcqhKOYYIcJShQfaoKJYPqvkPSxwETpMPM6BDS98ixpHJaRDvbmqFA9y+LIgV2wBw4AAhVQBVegBuqAgEfwDF7Bm/FkvBjvxsekdM7IenbAHxhfPyEfnU4=</latexit><latexit sha1_base64="1IkbeNwFzqpHyLOWl7Av/sV7vi0=">AAACGXicbVDLSgMxFM34rPU16tJNsAgu2jIRsW6EqgguXFSwD+yMQyZN29DMgyQjlGF+w42/4saFIi515d+YtrPQ1gMhJ+fcy809XsSZVJb1bczNLywuLedW8qtr6xub5tZ2Q4axILROQh6Klocl5SygdcUUp61IUOx7nDa9wcXIbz5QIVkY3KphRB0f9wLWZQQrLbmmJdxreAqtMoJ28dJNUCW1i+duUjpO75MS0o+77LaFDwcRcc2CVbbGgLMEZaQAMtRc89PuhCT2aaAIx1K2kRUpJ8FCMcJpmrdjSSNMBrhH25oG2KfSScabpXBfKx3YDYU+gYJj9XdHgn0ph76nK32s+nLaG4n/ee1YdU+chAVRrGhAJoO6MYcqhKOYYIcJShQfaoKJYPqvkPSxwETpMPM6BDS98ixpHJaRDvbmqFA9y+LIgV2wBw4AAhVQBVegBuqAgEfwDF7Bm/FkvBjvxsekdM7IenbAHxhfPyEfnU4=</latexit><latexit sha1_base64="1IkbeNwFzqpHyLOWl7Av/sV7vi0=">AAACGXicbVDLSgMxFM34rPU16tJNsAgu2jIRsW6EqgguXFSwD+yMQyZN29DMgyQjlGF+w42/4saFIi515d+YtrPQ1gMhJ+fcy809XsSZVJb1bczNLywuLedW8qtr6xub5tZ2Q4axILROQh6Klocl5SygdcUUp61IUOx7nDa9wcXIbz5QIVkY3KphRB0f9wLWZQQrLbmmJdxreAqtMoJ28dJNUCW1i+duUjpO75MS0o+77LaFDwcRcc2CVbbGgLMEZaQAMtRc89PuhCT2aaAIx1K2kRUpJ8FCMcJpmrdjSSNMBrhH25oG2KfSScabpXBfKx3YDYU+gYJj9XdHgn0ph76nK32s+nLaG4n/ee1YdU+chAVRrGhAJoO6MYcqhKOYYIcJShQfaoKJYPqvkPSxwETpMPM6BDS98ixpHJaRDvbmqFA9y+LIgV2wBw4AAhVQBVegBuqAgEfwDF7Bm/FkvBjvxsekdM7IenbAHxhfPyEfnU4=</latexit><latexit sha1_base64="1IkbeNwFzqpHyLOWl7Av/sV7vi0=">AAACGXicbVDLSgMxFM34rPU16tJNsAgu2jIRsW6EqgguXFSwD+yMQyZN29DMgyQjlGF+w42/4saFIi515d+YtrPQ1gMhJ+fcy809XsSZVJb1bczNLywuLedW8qtr6xub5tZ2Q4axILROQh6Klocl5SygdcUUp61IUOx7nDa9wcXIbz5QIVkY3KphRB0f9wLWZQQrLbmmJdxreAqtMoJ28dJNUCW1i+duUjpO75MS0o+77LaFDwcRcc2CVbbGgLMEZaQAMtRc89PuhCT2aaAIx1K2kRUpJ8FCMcJpmrdjSSNMBrhH25oG2KfSScabpXBfKx3YDYU+gYJj9XdHgn0ph76nK32s+nLaG4n/ee1YdU+chAVRrGhAJoO6MYcqhKOYYIcJShQfaoKJYPqvkPSxwETpMPM6BDS98ixpHJaRDvbmqFA9y+LIgV2wBw4AAhVQBVegBuqAgEfwDF7Bm/FkvBjvxsekdM7IenbAHxhfPyEfnU4=</latexit>
Field Correlation Length
l0 ⇠ 20 kpc
KF & Murase Nature Physics (2018)Dtotal ⇠ tcluster
Particle Trajectory in the Intracluster Medium - 0.1 EeV
20
Bddvnvmbujpo!bu!mpx!F
Tpgufs!tqfdusvn!evf!up!DS!ftdbqf
Bc = 10µG,M = 1015 M�
Neutrino Spectrum from One Cluster
21
Injection Composition = Galactic CR abundance
IceCube (>100 TeV)
UHECRs
Non-blazar Extragalactic Gamma-ray Background
Cosmic Particles from Black Hole Jets in Galaxy ClustersKF & Murase Nature Physics (2018)
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Fits to UHECR data
KF & Murase (2018)
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Accretion Shocks around Galaxy Cluster
Due to low baryon density at the outskirts of clusters, particle interaction near accretion shocks is too weak to explain observed high-energy neutrinos.
KF & Olinto (2017)
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• Sources of high-energy neutrinos and ultrahigh energy cosmic rays are abundant and powerful
• Cosmic-ray acceleration and confinement commonly exist in astrophysical environments
• A “common origin” of cosmic particles may be explained by black hole jets in galaxy clusters
Conclusion
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• What’s your targeted physics in next decade? Sources of high-energy neutrinos High-energy messengers (gamma rays and neutrinos) from transients such as TDEs, binary mergers
• What we need to accomplish? Design and planning of next-generation astroparticle experiments Data analysis infrastructures that enable collaboration of different experiments
Conclusion
26
Cosmic Ray Production by the Jet
Cosmic rays that are confined by the radio lobes cool adiabatically
*taking a typical lobe size 10 kpc, coherence length 0.3 kpc, magnetic field strength 5 muG, and expansion velocity 2000 km/s.
Only particles above ~PeV leave the source
*tlobedi↵ ⇠ 6.1
✓E/Z
1PeV
◆�1/3
Myr
tcool ⇠ 5Myr
E ⇠ Z 1019✓
B
1µG
◆✓R
10 kpc
◆eV
27
Neutrino Sources are Powerful and Abundant!
KF, Metzger, Vurm, Aydi, Chomiuk (2020)
Transients powered by non-relativistic shocks can barely explain the IceCube diffuse neutrinos.
106 107 108 109 1010
vsh [cm s°1]
104
105
106
107
A/A
§
Lsh = 1036 1040 1044
tpk = 3
tpk = 30
tpk = 300
Emax = 1012 1014 1016
radiative adiabatic
tcool = tpk tpp = tpk
novae
LRN
SLSNe-ISLSNe-II
SN-IIn
CCSNe
TDE
FBOT
Luminous FBOT
Ia-CSM
1010 1012 1014 1016 1018 1020
Emax [eV]
1042
1043
1044
1045
1046
1047
E opt[e
rgM
pc°
3yr
°1 ]
novae
SLSNe-I
SLSNe-II
SN-IIn
CCSNeTDE
FBOT
Luminous FBOTIa-CSM
≤rel <1%
≤rel <100%
E∫ > 100 TeV
