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Ultra-High Energy Cosmic ray and Neutrino Physics using the Moon. Olaf Scholten For the NuMoon collaboration KVI, Groningen. Physics of Cosmic rays. 10 4. Spectrum is power law Flux ~ E -3 Non thermal spectrum! There must be sources! Where? What? End point? This talk:
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Ultra-High Energy Cosmic ray and Neutrino Physics using the Moon Olaf Scholten For the NuMoon collaboration KVI, Groningen Hamburg 2008
Physics of Cosmic rays 104 Spectrum is power law Flux ~ E-3 Non thermal spectrum! There must be sources! Where? What? End point? This talk: Measurement at highest E (Area Moon = 2 107 km2) ← 1 [m-2 s-1] E-2.7 ← 32 orders of magnitude F(E) [ m2 sr s GeV ] -1 UHECR 1 [km-2 y-1] ← 12 orders of magnitude 10-28 109 1021 E [eV ] Hamburg 2008
Principle of the measurement Cosmic ray or neutrino Detection: LOFAR 107 km2 100MHz Radio waves Hamburg 2008
~2 m Cosmic ray or neutrino ~10 cm shower Wave front Askaryan effect: Coherent Cherenkov emission • Leading cloud of electrons, v c Typical size of order 10cm Coherent Čerenkov for ν 2-5 GHz cos θc =1/n , θc=56o for ∞ shower length • Length of shower, L few m Important for angular spreading nano second pulses Hamburg 2008
NuMoon Experiment @ WSRT Use Westerbork radio observatory 4 frequencies Hamburg 2008
18 TB raw data per 6 hr slot Time Frequency Excise RFI Trigger + dedispersion Hamburg 2008 Trigger: pulse in all four frequency bands
Trigger Power Spectrum Effect successive steps in analysis Gaussian noise Hamburg 2008
Prelimenary Results Analysis of 20 h data Data taking is continuing NuMoon collaboration: O.S., Stijn Buitink, Heino Falcke, Ben Stappers, Kalpana Singh, Richard Strom Hamburg 2008
Future: LOFAR LOFAR Core 1 month E-LOFAR, 1 year SKA, 1 year, LFB: 100-300 MHz MFB: 300-500 MHz From: O.S., SKA Design Study report Hamburg 2008
Conclusions Detection of Ultra-High Enegy cosmic rays & neutrinos Physics: What are the sources? Challenge: implement real-time trigger in CEP LOFAR as observer of short (n-sec) intermittent pulses. Hamburg 2008