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UltraHigh Energy Neutrino Fluxes

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The cosmogenic neutrino flux produced by pion production by cosmic rays ... from hadronic interactions up to ~1016 eV and 'cosmogenic' neutrinos ... – PowerPoint PPT presentation

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Title: UltraHigh Energy Neutrino Fluxes


1
Ultra-High Energy Neutrino Fluxes
  • HENA workshop
  • Paris June 16-17
  • Neutrinos A general connection to cosmic rays
  • Neutrino fluxes in top-down models
  • The Z-burst
  • Summary

Günter Sigl GReCO, Institut dAstrophysique de
Paris, CNRS http//www.iap.fr/users/sigl/homepage.
html
2
Ultra-High Energy Cosmic Rays and the Connection
to ?-ray and Neutrino Astrophysics
accelerated protons interact
gt energy fluences in ?-rays and neutrinos
are comparable due to isospin symmetry.
The neutrino spectrum is unmodified, whereas
?-rays pile up below the pair production
threshold on the CMB at a few 1014 eV.
The Universe acts as a calorimeter for the total
injected electromagnetic energy above the pair
threshold. This constrains the neutrino fluxes.
3
A possible acceleration site associated with
shocks in hot spots of active galaxies
4
The total injected electromagnetic energy is
constrained by the diffuse ?-ray flux measured by
EGRET in the MeV 100 GeV regime
5
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6
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7
The cosmogenic neutrino flux produced by pion
production by cosmic rays during propagation can
violate the Waxman-Bahcall bound for
injection spectra harder than E-1.5 and source
luminosities increasing with redshift
WB bound
?-ray and cosmic ray fluxes must be consistent
with observations.
Kalashev, Kuzmin, Semikoz, Sigl, PRD 66 (2002)
063004
8
Example diffuse sources injecting E-1 proton
spectrum extending up to 2x1022 eV with (1z)3 up
to redshift z2. Shown are primary proton
flux together with secondary ?-ray and neutrino
fluxes.
g
ni
9
GLUE
10
Future neutrino flux sensitivities
Kalashev, Kuzmin, Semikoz, Sigl, PRD 66 (2002)
063004
11
Flux calculations in Top-Down scenarios
c) fold in injection history and solve the
transport equations for propagation
12
A typical example
Kalashev, Kuzmin, Semikoz, Sigl, PRD 66 (2002)
063004
13
New Particles and New Interactions
Motivated by possible correlations with high
redshift objects
If this is confirmed, one can only think of 3
possibilities
1.) Neutrino primaries but Standard Model
interaction probability in atmosphere is 10-5.
  • resonant (Z0) secondary production on massive
    relic neutrinos
  • needs extreme parameters and huge neutrino
    fluxes.
  • strong interactions above 1TeV only moderate
    neutrino fluxes required.

2.) New heavy neutral (SUSY) hadron X0 m(X0) gt
mN increases GZK threshold. but basically
ruled out by constraints from accelerator
experiments.
3.) New weakly interacting light (keV-MeV)
neutral particle electromagnetic coupling
small enough to avoid GZK effect hadronic
coupling large enough to allow normal air
showers very tough to do.
In all cases more potential sources, BUT charged
primary to be accelerated to even higher energies.
14
The Z-burst mechanism Relevant neutrino
interactions
15
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16
The Z-burst mechanism Sources emitting neutrinos
and ?-rays
Kalashev, Kuzmin, Semikoz, Sigl, PRD 65 (2002)
103003
Sources with constant comoving luminosity density
up to z3, with E-2 ?-ray injection up to 100 TeV
of energy fluence equal to neutrinos, m?0.5eV,
B10-9 G.
17
The Z-burst mechanism Exclusive neutrino emitters
Kalashev, Kuzmin, Semikoz, Sigl, PRD 65 (2002)
103003
Sources with comoving luminosity proportional to
(1z)m up to z3, m?0.5eV, B10-9 G.
18
A compilation of neutrino flux predictions
Cline, Stecker, astro-ph/0003459
19
Conclusions
1.) Pion-production establishes a very important
link between the physics of high energy
cosmic rays on the one hand, and ?-ray and
neutrino astrophysics on the other hand. All
three of these fields should be considered
together.
2.) There are many potential high energy neutrino
sources including speculative ones. But the
only guaranteed ones are due to pion
production of primary cosmic rays known to exist
Galactic neutrinos from hadronic
interactions up to 1016 eV and cosmogenic
neutrinos around 1019 eV from photopion
production. Flux uncertainties stem from
uncertainties in cosmic ray source distribution
and evolution.
3.) The highest fluxes above 1019 eV are
predicted by top-down models, the Z-burst,
and cosmic ray sources with power increasing with
redshift.
4.) The coming 3-5 years promise an about
100-fold increase of ultra-high energy
cosmic ray data due to experiments that are
either under construction or in the proposal
stage. This will constrain primary cosmic
ray flux models.
5.) Many new interesting ideas on a modest cost
scale for ultra-high energy neutrino
detection are currently under discussion, see
experimental talks.
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