R. Haeusler scite author profile

The attenuation of the electron shower size beyond the shower maximum is studied with the KASCADE extensive air shower experiment in the primary energy range of about 10 14 − 10 16 eV. Attenuation and absorption lengths are determined by applying different approaches, including the method of constant intensity, the decrease of the flux of extensive air showers with increasing zenith angle, and its variation with ground pressure. We observe a significant dependence of the results on the applied method. The determined values of the attenuation length ranges from 175 to 196 g/cm 2 and of the absorption length from 100 to 120 g/cm 2 . The origin of these differences is discussed emphasizing the influence of intrinsic shower fluctuations.

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The cosmic-ray experiment KASCADE

Antoni

Apel²,

Badea

et al. 2003

Nuclear Instruments and Methods in Physics Research Section A:

347

159

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Electron, muon, and hadron lateral distributions measured in air showers by the KASCADE experiment

Antoni¹,

Apel²,

Badea³

et al. 2001

Astroparticle Physics

100

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Muon density measurements with the KASCADE central detector

Antoni¹,

Apel²,

Badea³

et al. 2002

Astroparticle Physics

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A non-parametric approach to infer the energy spectrum and the mass composition of cosmic rays

Antoni¹,

Apel²,

Badea³

et al. 2002

Astroparticle Physics

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The experiment KASCADE observes simultaneously the electron-photon, muon, and hadron components of high-energy extensive air showers (EAS). The analysis of EAS observables for an estimate of energy and mass of the primary particle invokes extensive Monte Carlo simulations of the EAS development for preparing reference patterns. The present studies utilize the air shower simulation code CORSIKA with the hadronic interaction models VENUS, QGSJet and Sibyll, including simulations of the detector response and efficiency. By applying non-parametric techniques the measured data have been analyzed in an event-by-event mode and the mass and energy of the EAS inducing particles are reconstructed. Special emphasis is given to methodical limitations and the dependence of the results on the hadronic interaction model used. The results obtained from KASCADE data reproduce the knee in the primary spectrum, but reveal a strong model dependence. Owing to the systematic uncertainties introduced by the hadronic interaction models no strong change of chemical composition can be claimed in the energy range around the knee.

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R. Haeusler

Measurements of attenuation and absorption lengths with the KASCADE experiment

The cosmic-ray experiment KASCADE

Electron, muon, and hadron lateral distributions measured in air showers by the KASCADE experiment

Muon density measurements with the KASCADE central detector

A non-parametric approach to infer the energy spectrum and the mass composition of cosmic rays

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