Measurement of the UHECR energy spectrum from hybrid data of the Pierre Auger Observatory Presenter: Lorenzo Perrone Università del Salento and INFN Lecce.

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Presentation transcript:

Measurement of the UHECR energy spectrum from hybrid data of the Pierre Auger Observatory Presenter: Lorenzo Perrone Università del Salento and INFN Lecce – Italy 30th International Cosmic Ray Conference July , 2007, Merida, Yucatan, Mexico The Pierre Auger Collaboration

Outline - The Pierre Auger Observatory and the hybrid concept “In order to make further progress, particularly in the field of cosmic rays, it will be necessary to apply all our resources and apparatus simultaneously and side-by-side.” V.H.Hess, Nobel Lecture, December 1936

Outline - The Pierre Auger Observatory and the hybrid concept “In order to make further progress, particularly in the field of cosmic rays, it will be necessary to apply all our resources and apparatus simultaneously and side-by-side.” V.H.Hess, Nobel Lecture, December Hybrid trigger efficiency and time dependent simulation

Outline - The Pierre Auger Observatory and the hybrid concept “In order to make further progress, particularly in the field of cosmic rays, it will be necessary to apply all our resources and apparatus simultaneously and side-by-side.” V.H.Hess, Nobel Lecture, December Hybrid trigger efficiency and time dependent simulation - Data selection, uptime and exposure

Outline - The Pierre Auger Observatory and the hybrid concept “In order to make further progress, particularly in the field of cosmic rays, it will be necessary to apply all our resources and apparatus simultaneously and side-by-side.” V.H.Hess, Nobel Lecture, December Hybrid trigger efficiency and time dependent simulation - Data selection, uptime and exposure - Energy spectrum from hybrid data

Outline - The Pierre Auger Observatory and the hybrid concept “In order to make further progress, particularly in the field of cosmic rays, it will be necessary to apply all our resources and apparatus simultaneously and side-by-side.” V.H.Hess, Nobel Lecture, December Hybrid trigger efficiency and time dependent simulation - Data selection, uptime and exposure - Energy spectrum from hybrid data - Systematic uncertainties

The Hybrid Concept The Auger Observatory combines independent measurement techniques reliable geometry and energy measurement mass composition studies in a complementary way Surface Detector Array (SD) Air Fluorescence Detectors (FD) Event id:

Hybrid reconstruction

Hybrid Exposure: strategy and simulation flow For each active tank within a given radius, the single tank trigger probability is calculated as a function of core distance to shower axis based on parametrised functions [Lateral Trigger Probability Functions(*)] - Complete and time dependent simulation of FD response (*) D. Allard for the The Pierre Auger Coll. ICRC 2005 (Pune), India A study with full (and simultaneous) simulations of FD and SD detector response with Corsika Showers has validated the used parameterisation for E > eV - Simulation of SD timing with a realistic and time dependent array layout

Hybrid Trigger Efficiency Full efficiency No dependence on mass composition FD and SD response fully and simultaneously simulated CORSIKA showers Fraction of FD events with at least 1 SD station E > eV:

Simulation compared to data Time dependent simulation agrees fairly good with data (tightest selection level)

Data selection Profile quality cuts Geometry quality cuts [1] M. Unger for the The Pierre Auger Collaboration, at this Conference [2] The Pierre Auger Collaboration, Astroparticle Phys. 27 (2007) 155 entries: entries Sel. events: E >10 18 eV Data sample from 1/12/04 to 28/2/2007 zenith angle < 60° core distance to tank < 750 m shower long. profile within the geometrical f.o.v [1] core distance to FD telescope within a given fiducial volume [2] measurement of atmospheric parameters available X max observed energy reconstruction uncertainties < 20% relative amount of Cherenkov light < 50% a successful Gaisser-Hillas fit  2 /ndof < 2.5

Hybrid Exposure: Uptime Hybrid detector uptime after different sources of detector inefficiency LLLMLACO LL : Los Leones LM: Los Morados LA : Loma Amarilla CO: Coihueco DAQ – Data acquisition on\off SLC – Slow control (shutters status) Lidar activity veto High rate veto

Hybrid Exposure Hybrid Exposure at the tightest selection level

Hybrid Spectrum Only statistical uncertainties given

Good agreement found within the systematic uncertainties Hybrid vs SD Spectrum

Good agreement among individual measurements by different eyes Hybrid Spectrum (II)

Systematics uncertainties Uptime (  4% from a cross-check with CLF lasers Atmospheric conditions (atm.) 16% due to cloud coverage Event Selection (sel.) 15% (E=10 18 eV) SD uncorrelated uncertainties 22% uncertainty on the energy scale(*)SD correlated uncertainty Overall and individual uncertainties (added in quadrature) (*) B. Dawson for the The Pierre Auger Collaboration, at this Conference

Conclusions A measurement of the UHECR energy spectrum from hybrid data of the Pierre Auger Observatory presented (E > eV). Data sample extend over a time of more than two years in which FD and SD have grown significantly A realistic and time dependent simulation performed in order to evaluate in detail the exposure of the hybrid detector Good agreement with the SD spectrum found within the expected systematic uncertainties