Abstract
We study the propagation of Čerenkov photons generated by Very HighEnergy γ-rays and hadrons in the atmosphere. The photon productionheight distributions are estimated from semi-empirical methods andcompared with those derived by standard simulation techniques. Incidentspectra at various observation altitudes are then derived after applyingwavelength dependent corrections due to photon attenuation in theatmosphere during the propagation of photons from the height of productionto the height of observation. These are generated both for γ-ray and hadron primaries of various energies. The derivedproduction height distributions agree very well with those generated bythe simulation package `CORSIKA' at all energies and for both γ-ray and proton primaries. The incident photon spectra are found to beboth altitude and primary energy dependent. The peak ofthe incident spectrum shifts towards the shorter wavelength withincreasing altitude of observation for a given primary. Also the peak ofthe photon spectrum shifts towards the shorter wavelength withincreasing energy of the primary at a given altitude. The fraction of the UVcomponent in the incident Čerenkov spectrum is estimated both forγ-ray and hadronic primaries at various observation altitudes andenergies. Hadron generated Čerenkov spectra are marginally richer in UVlight and the difference increases slightly at higher altitudes. The fraction of the UV to the visible light in the Čerenkov spectrum could be a usefulparameter to separate γ-rays from cosmic ray background only if onecan measure this fraction very accurately.
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Rahman, M.A., Bhat, P.N., Acharya, B.S. et al. Gamma Ray and Hadron generated Čerenkov Photon Spectra at Various Observation Altitudes. Experimental Astronomy 11, 113–131 (2001). https://doi.org/10.1023/A:1011147629627
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DOI: https://doi.org/10.1023/A:1011147629627