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GZK EHE detection What is the GZK mechanism? EHE  Propagation in the Earth Expected intensities at the IceCube depth Atmospheric  – background Event.

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Presentation on theme: "GZK EHE detection What is the GZK mechanism? EHE  Propagation in the Earth Expected intensities at the IceCube depth Atmospheric  – background Event."— Presentation transcript:

1 GZK EHE detection What is the GZK mechanism? EHE  Propagation in the Earth Expected intensities at the IceCube depth Atmospheric  – background Event rate TAUP 2003

2 GZK Neutrino Production 2.725 K 411 photons / cm 3 0.6 x 10 -27 cm 2 γ p n p π + μ + ν e + ν γ E = 10 20 eV E 0.8 x 10 20 eV ~ Conventional Mechanism of EHE neutrinos!!

3 TAUP 2003 Yoshida and Teshima 1993 Yoshida, Dai, Jui, Sommers 1997 Note: The oscillations convert e,  to e, , 

4 TAUP 2003  /  propagation in Earth

5 e e      e/     Weak Incoming Products Weak Cascades Decay Weak Pair/decay Bremss Pair PhotoNucl. Decay Pair Pair Bremss Decay Weak Decay

6 TAUP 2003 Tau(Neutrinos) from    Suppression By  decay Muon(Neutrinos) from   Nadir Angle

7 1.4 km 1km Upward Ice Rock ν ± π γ ν + e - e 1km Downward ν γ γ + e - e lepton

8 TAUP 2003 Upward-goingDownward going!! Atmospheric muon! – a major backgrond But so steep spectrum

9 TAUP 2003 Down-going events dominates… 1400 m 2800 m 11000m UpDown Atmospheric  is strongly attenuated…

10 Flux as a function of energy deposit in km 3 dE/dX~  E  E~  XbE

11 TAUP 2003 UpDown

12 TAUP 2003 Intensity of EHE  and  GZK m=4 Z max =4 I  (E>10PeV)I  (E>10PeV) RATE [/yr/ km 2 ] Down 5.90 10 -19 5.97 10 -19 0.37 Up 3.91 10 -20 6.63 10 -20 0.03 I  (E>10PeV) Energy Deposit I  (E>10PeV) Energy Deposit Down 4.75 10 -19 2.94 10 -19 0.24 m=7 Z max =5 Down 7.21 10 -17 4.83 10 -17 37.9 Atm  1.74 10 -19 0.05 [cm -2 sec -1 ]

13 E µ =10 TeV ≈ 90 hitsE µ =6 PeV ≈ 1000 hits How EHE events look like The typical light cylinder generated by a muon of 100 GeV is 20 m, 1PeV 400 m, 1EeV it is about 600 to 700 m.

14 TAUP 2003 Conclusion  appeared in 10 PeV- EeV are our prime target on GZK detection. 1/100-1/500 of primary  intensity! Downward  and  make main contributions in PeV -EeV Energy Estimation would be a key for the bg reduction Because atmospheric  spectrum ~ E -3.7 GZK is DETECTABLE by IceCube 0.2-40 events/year (BG 0.05 events/year) IceCube has great capability for TeV-PeV -induced muons taking advantage of long range in the clear ice. For EHE like the GZK….

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