Study of the effect of the primary particles composition in the lateral distribution of air showers from the Pierre Auger Observatory

The energy of ultra high energy cosmic rays can be estimated from the lateral distribution function (LDF) of the shower as measured by surface detectors. The LDF describes the particle density as a function of the distance from the shower center. However, with the exception of the position of the shower center, no other information is extracted from it, may because it does not have a parametrization or an analytic function that describes it completely. The first interactions of cosmic rays with the atmosphere are decisive for the development of the extensive air showers. Such interactions, among other things, depend on the chemical composition of comic rays. Differences in these interactions can cause changes in the fluctuation shape of lateral distribution. Through simulations of showers with different primary particles it may be possible to estimate the composition of ultra high energy cosmic rays comparing the fluctuation shape of the lateral distributions of real events with those from simulated ones. One of the quantities relevant to the fluctuation of the LDF signal is the uncertainty of the stations. The analysis framework of the Pierre Auger Observatory applies a correction to the signal uncertainty of the signal. The parameterization of this correction is obtained empirically. In this work a statistical justification for this correction is proposed and is related to distribution of the signal which is not Poisson, but a composition of processes with different distributions. For this work a library of showers using two simulators of air showers, AIRES and CORSIKA, was produced. The showers simulated with the AIRES used SIBYLL as a hadronic interaction model while COSIKA used EPOS. Showers initiated by protons and iron nuclei with the two simulators were produced, and their angular distribution was considered isotropic. The energy distribution of these events follows a power law and ranges from 1 to 200 EeV. Using the Nishimura, Kamata and Greisen (NKG) function as a parameterization for the LDF, one obtains residues that are systematically positive at stations further from the center of the shower. These stations have a signalclose to the trigger level. One of the hypothesis raised in other works for this behavior is that it is related to the influence of the silent stations, but this work shows that their use has little impact on the fluctuation shape of the LDF. In fact, this effect is caused because the parametrizations of LDF in the Offline ignore that the signals of the stations have a cut due to the trigger, ie, the probability density function that describes the real signal is not the same that describes the observed signal. This work proposes a correction to the parameterizations of the LDF and implements it in the Offline. As a result of this correction, the residues, which were always positive, are significantly reduced and compatible with zero. In this study three independent analysis were performed to compare real and simulated events, two of them not dependent directly of the LDF fit and also not sensitive to the primary particle energy. They allow a comparison between the signals assuming a simple relationship between them. The first case assumes that the difference in signal is due to the muonic component of the shower and the second assumes that the two compared sets of events are well described by NKG functions but with different S1000. The third analysis uses the residues of the LDF fits and is able to observe the composition of as a function of primary particle energy. This last analysis was performed using the NKG function with and without correction of the trigger effect. The different analysis used to estimate the composition of cosmic rays showed results consistent, despite the limitations found in some of them. The primary particle composition obtained from the surface detectors in this work is consistent with the results derived from the elongation rate measured by the fluorescence detectors, supporting the hypotesis that the composition of cosmic rays is predominantly proton becoming heavier for energies above 10 EeV. (AU)