Alba Cappa Universita’ and INFN Torino Čerenkov Light Measurements for the EUSO Experiment Rencontres de Moriond – Very High Energy Phenomena in the Universe.

Slides:



Advertisements
Similar presentations
Trigger issues for KM3NeT the large scale underwater neutrino telescope the project objectives design aspects from the KM3NeT TDR trigger issues outlook.
Advertisements

Stereo Spectrum of UHECR Showers at the HiRes Detector  The Measurement Technique  Event Reconstruction  Monte Carlo Simulation  Aperture Determination.
The Composition of Ultra High Energy Cosmic Rays Through Hybrid Analysis at Telescope Array Elliott Barcikowski PhD Defense University of Utah, Department.
Results from the Telescope Array experiment H. Tokuno Tokyo Tech The Telescope Array Collaboration 1.
Use of floating surface detector stations for the calibration of a deep-sea neutrino telescope G. Bourlis, N. A. B. Gizani, A. Leisos, A. G. Tsirigotis,
The Pierre Auger Observatory Nicolás G. Busca Fermilab-University of Chicago FNAL User’s Meeting, May 2006.
TeVPA, July , SLAC 1 Cosmic rays at the knee and above with IceTop and IceCube Serap Tilav for The IceCube Collaboration South Pole 4 Feb 2009.
EUSO: Extreme Universe Space Observatory Jessica Cerny Bancroft-Rosalie School.
AGASA update M. Teshima ICRR, U of CfCP mini workshop Oct
First Analysis of the Auger APF Light Source Eli Visbal (Carnegie Mellon University) Advisor: Stefan Westerhoff.
Characterization of Orbiting Wide-angle Light-collectors (OWL) By: Rasha Usama Abbasi.
Special Issues on Neutrino Telescopy Apostolos G. Tsirigotis Hellenic Open University School of Science & Technology Particle and Astroparticle Physics.
S. E. Tzamarias The project is co-funded by the European Social Fund & National Resources EPEAEK-II (PYTHAGORAS) KM3Net Kick-off Meeting, Erlangen-Nuremberg,
E.Plagnol - HENA June The EUSO Project ë An overview of the Physics of EUSO ë Detection of UHECR by fluorescence +Cerenkov ë The EUSO detector.
HOU Reconstruction & Simulation (HOURS): A complete simulation and reconstruction package for Very Large Volume underwater neutrino Telescopes. A.Leisos,
EHE Search for EHE neutrinos with the IceCube detector Aya Ishihara for the IceCube collaboration Chiba University.
Report of the HOU contribution to KM3NeT TDR (WP2) A. G. Tsirigotis In the framework of the KM3NeT Design Study WP2 Meeting - Marseilles, 29June-3 July.
Size and Energy Spectra of incident cosmic radiation obtained by the MAKET - ANI surface array on mountain Aragats. (Final results from MAKET-ANI detector)‏
Special Issues on Neutrino Telescopy Apostolos G. Tsirigotis Hellenic Open University School of Science & Technology Particle and Astroparticle Physics.
The Second International Workshop on Ultra-high-energy cosmic rays and their sources INR, Moscow, April 14-16, 2005 from Extreme Universe Space Observatory.
A new approach to EAS investigations in energy region eV R.P.Kokoulin for DECOR Collaboration Moscow Engineering Physics Institute, Russia.
Performance of CRTNT for Sub-EeV Cosmoc Ray Measurement Zhen Cao IHEP, Beijing & Univ. of Utah, SLC Aspen, CO, 04/2005.
Preliminary MC study on the GRAND prototype scintillator array Feng Zhaoyang Institute of High Energy Physics, CAS, China GRAND Workshop, Paris, Feb. 015.
EAS Reconstruction with Cerenkov Photons Shower Simulation Reconstruction Algorithm Toy MC Study Two Detector Configuration Summary M.Z. Wang and C.C.
Atmospheric shower simulation studies with CORSIKA Physics Department Atreidis George ARISTOTLE UNIVERSITY OF THESSALONIKI.
Report of the HOU contribution to KM3NeT TDR (WP2) A. G. Tsirigotis In the framework of the KM3NeT Design Study WP2 Meeting - Erlangen, May 2009.
Atmospheric Aerosol Measurements at the Pierre Auger Observatory The Pierre Auger Observatory operates an array of monitoring devices to record the atmospheric.
Ronald Bruijn – 10 th APP Symposium Antares results and status Ronald Bruijn.
March 02, Shahid Hussain for the ICECUBE collaboration University of Delaware, USA.
WATER CHERENKOV DETECTOR ARRAY at the University of Puebla to study cosmic rays H. Salazar, J. Cotzomi, E. Moreno, T.Murrieta, B.Palma, E.Perez, L. Villaseñor.
Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope.
NESTOR SIMULATION TOOLS AND METHODS Antonis Leisos Hellenic Open University Vlvnt Workhop.
Ultra High Energy Cosmic Rays -- Origin and Propagation of UHECRs -- M.Teshima Max-Planck-Institut f ü r Physik, M ü nchen Erice Summer School July
Humberto Salazar (FCFM-BUAP) for the Pierre Auger Collaboration, CTEQ- Fermilab School Lima, Peru, August 2012 Ultrahigh Cosmic Rays: The highest energy.
E.Plagnol - TA/TALE feb Acceptance and Counting Rates of EUSO ë Detecting UHECR from space ë The EUSO detector : Who does what. ë Some characteristics.
Claudio Di Giulio University of Roma Tor Vergata, INFN of Roma Tor Vergata IDAPP 2D Meeting, Ferrara, May The origin and nature of cosmic rays above.
Status and first results of the KASCADE-Grande experiment
AGASA Results Masahiro Teshima for AGASA collaboration
XXXI International Cosmic Ray Conference, ICRC 2009 Lodz, Poland, July 7-15, 2009 Time structure of the Extensive Air Shower front with the ARGO-YBJ experiment.
Detection of electromagnetic showers along muon tracks Salvatore Mangano (IFIC)
Stefano Argirò 1 for the Auger Collaboration 1 University of Torino, Italy, and INFN Physics case The Auger Observatory Performance Preliminary Analysis.
Hadronic interaction studies with the ARGO-YBJ experiment (5,800 m 2 ) 10 Pads (56 x 62 cm 2 ) for each RPC 8 Strips (6.5 x 62 cm 2 ) for each Pad ( 
CODALEMA A Cosmic Ray Radio Detection Array ICRC 2007, 3-11 July Merida, Mexico CODALEMA A Cosmic Ray Radio Detection Array Didier Lebrun, LPSC Grenoble.
Hybrid measurement of CR light component spectrum by using ARGO-YBJ and WFCTA Shoushan Zhang on behalf of LHAASO collaboration and ARGO-YBJ collaboration.
1 João Espadanal, Patricia Gonçalves, Mário Pimenta Santiago de Compostela 3 rd IDPASC school Auger LIP Group 3D simulation Of Extensive Air.
The Auger Observatory for High-Energy Cosmic Rays G.Matthiae University of Roma II and INFN For the Pierre Auger Collaboration The physics case Pierre.
June 6, 2006 CALOR 2006 E. Hays University of Chicago / Argonne National Lab VERITAS Imaging Calorimetry at Very High Energies.
Cosmic ray physics in ALICE Katherin Shtejer Díaz For the ALICE Collaboration LatinoAmerican Workshop on High Energy Physics: Particles and Strings, Havana,
Geant4 Simulation of the Pierre Auger Fluorescence Detector
Study of VHE Cosmic Ray Spectrum by means of Muon Density Measurements at Ground Level I.I. Yashin Moscow Engineering Physics Institute,
What we do know about cosmic rays at energies above eV? A.A.Petrukhin Contents 4 th Round Table, December , Introduction. 2. How these.
Z. Cao, H.H. He, J.L. Liu, M. Zha Y. Zhang The 2 nd workshop of air shower detection at high altitude.
Preliminary Profile Reconstruction of EA Hybrid Showers Bruce Dawson & Luis Prado Jr thanks to Brian Fick & Paul Sommers and Stefano Argiro & Andrea de.
Detecting Air Showers on the Ground
RADIODETECTION AND CHARACTERIZATION OF THE COSMIC RAYS AIR SHOWER RADIO EMISSION FOR ENERGIES HIGHER THAN eV WITH THE CODALEMA EXPERIMENT Thomas.
NEVOD-DECOR experiment: results and future A.A.Petrukhin for Russian-Italian Collaboration Contents MSU, May 16, New method of EAS investigations.
L. CazónHadron-Hadron & Cosmic-Rays interactions at multi-TeV energies. Trento,2-Dez Results from the Pierre Auger Observatory L. Cazon, for the.
Space-time structure of signals in scintillation detectors of EAS L.G. Dedenko, G.F. Fedorova, T.M. Roganova and D.A. Podgrudkov.
 What are Cosmic Rays? A short history What do we know now about CRs  What are Extensive Air Showers? A short history How to detect EAS? Back to CR –
1 Cosmic Ray Physics with IceTop and IceCube Serap Tilav University of Delaware for The IceCube Collaboration ISVHECRI2010 June 28 - July 2, 2010 Fermilab.
A Measurement of the Ultra-High Energy Cosmic Ray Spectrum with the HiRes FADC Detector (HiRes-2) Andreas Zech (for the HiRes Collaboration) Rutgers University.
A Method of Shower Reconstruction from the Fluorescence Detector M.Giller, G.Wieczorek and the Lodz Auger group GZK-40 Moscow Workshop, May 2006.
completed in austral season South Pole completed in austral season.
The Antares Neutrino Telescope
Recent Results of Point Source Searches with the IceCube Neutrino Telescope Lake Louise Winter Institute 2009 Erik Strahler University of Wisconsin-Madison.
Ultra High Energy Cosmic Ray Spectrum Measured by HiRes Experiment
Pierre Auger Observatory Present and Future
Preliminary Profile Reconstruction of EA Hybrid Showers
Litao Zhao Liaoning University&IHEP
Atmospheric muons in ANTARES
Presentation transcript:

Alba Cappa Universita’ and INFN Torino Čerenkov Light Measurements for the EUSO Experiment Rencontres de Moriond – Very High Energy Phenomena in the Universe La Thuile, March 12-19, 2005

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 2 CONTENTS:  the ULTRA experiment for EUSO  the ULTRA detector  simulated and collected data  data analysis  conclusions

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 3 EUSO : an UHECRs observatory UHECRs spectrum EUSO will provide to solve some problems of Fundamental Physics and HE astrophysics: investigation of the highest energy processes in the Universe through the detection and investigation of the Extreme Energy component of the cosmic radiation (EECRs / UHECRs with E > 5×10 19 eV); arrival direction and small-scale clustering will provide informations on the origin of EECRs and magnetic fields; HE neutrino astronomy will probe the boundaries of the extreme Universe and the nature and distribution of EECRs sources. do the GZK cut-off exist?

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 4 The EUSO project EUSO geometrical design EUSO focal surface EUSO will look downwards to the Earth atmosphere. It will see the fluorescent UV traces isotropically produced by the charged secondary particles along the EAS development. EUSO will detect also the Cherenkov light emitted in a narrow cone centered on the shower axis and hitting the Earth surface, where it’s partially diffused. image of a shower from a UHE primary on the EUSO focal surface: fluorescent and Cherenkov signals. Cherenkov signal

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 5 ULTRA facility in the EUSO framework reflection/diffusion coefficient ? ULTRA UV Light Transmission and Reflection in the Atmosphere ULTRA goals: measurement of the EAS characteristics and associated Cherenkov light diffused by various surfaces.

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 6 ULTRA : a supporting activity for the EUSO project ULTRA : hybrid system UVscope ETscope UV optical unit for Cherenkov light detection EAS telescope, scintillator’s array ETscope detector: characterization of the triggering EAS (shower size, arrival direction, core position) and comparison with the results of the simulations. UVscope and ETscope work in coincidence to detect the EAS and the Cherenkov light generated and reflected/diffused back by the Earth surface.

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 7 Mont Cenis 1970 m a.s.l g/cm 2 LPSC Grenoble 216 m a.s.l g/cm 2 The ULTRA setup 2003/2004 Experimental Setup 4+1 counting stations distance between modules = 35/54 m standard NIM & CAMAC electronics / ACQ by Labview 4-fold coincidence 150 ns threshold: 0.3 VEM 2 couples of “Belenos” (Cherenkov light detectors) near to the central station, pointing to zenith and nadir. L=54 m ST3 ST4 ST1 ST5 ST2 B-UPB-DW

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 8 Scintillator NE102A 80x80 cm 2 x 4 cm Expected Light Yield ~40 p.e./m.i.p. 2 PMTs High/Low Gain HG pmt Saturation ~40 VEM / 0.64 m 2 LG pmt Saturation ~400 VEM / 0.64 m 2 Procedures for the triggering events: event by event for each station the following characteristics are known: - arrival time - deposited energy in the scintillator (number of VEMs) - position of the detectors RECONSTRUCTION arrival direction (  ) shower size N e (E o ) core position The ETscope detector

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 9 SIMULATIONS (I) Procedures for the simulated events: event by event for each station the following characteristics are known: - deposited energy in the scintillator (number of VEMs) - position of the detectors - true values for size and core position RECONSTRUCTION of the internal events shower size N e (E o ) core position resolution in the reco very important also for the reconstruction of the real data the ones having the core inside the array: UVscope FOV is limited to the dimensions of ETscope area

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 10 SIMULATIONS (II)  = 0 o, energy (eV)  = 20 o, energy (eV) 5* * * * * * * *10 16  primary particles type: protons;  2000 events for each energy and primary inclination;  two observation levels: 0m asl, 2000m asl. EAS simulation: CORSIKA simulations of EAS with QGSJET hadronic interaction model:

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 11 SIMULATIONS (III) detector simulation: a Monte Carlo program simulate the detector response to the showers generated by CORSIKA, for different geometrical configurations (the experimental conditions used in the measurement Capo Granitola). From the simulations we can predict the detector side that is required to have the best measurement the observation level of interest. study of the effective area optimization of the detector: calculation of the threshold energy measurement of the expected counting rate

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 12 Grenoble (winter campaign) : Mont-Cenis (2004 campaign) : Capo Granitola (spring-summer 2005 campaign) : SIMULATIONS (IV) Some results for: - effective area for internal events - effective area - convolution between the effective area and the CR spectrum E(GeV) A eff (m 2 ) A int (m 2 ) A eff AE -γ (m 2 )

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 13 Čerenkov light measurement (I) Tyvec Refecting- Diffusing Surface 2+2 optical units (Belenos-up & down) located near to the ETscope central station (1.5 cm Ø pmt + fresnel lens) / triggered by EAS events FOV = 30 o bottom oriented unit top oriented unit 2004 CAMPAIGN in this measurement campaign, we are interested to the detect em component in coincidence with diffused Cherenkov light. For this reason (and due to high beckground in Grenoble), we used a surface with a very high reflectivity coefficient.

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 14 The ETscope LPSC 937 events collected in 38.4 hours TRIGGER CONDITIONS: Data selected requiring the triggering of the central detector and the Belenos-up or the Belenos-down. Requiring a signal over threshold on the Belenos-up high energy shower are selected, and even higher requiring the Belenos-down. Measurement campaigns: 2004 (Mont-Cenis, Grenoble) winter (Grenoble) I will show the data analysis of the 2004 Grenoble

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe ± ± ± ± ± ±3.2 LPSC size spectrum Cherenkov light measurement (II) green: trigger of central station + Belenos-up red: trigger of Belenos-down LPSC zenith angle

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 16 blue points: Cherenkov l.d.f. obtained from events with core located within 20 meters to central station (absolute single-pe calibration used) background level: 3000 photons /(m 2 ns sr) (10 x Mont-Cenis background) green line: CORSIKA Simulation for eV proton, with wavelength in nm band. Cherenkov light measurement (III)

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 17 UP Oriented Unit (1) vs Event Number UP Oriented Unit (2) vs Event Number Twilight Cherenkov light measurement (IV) The signal measured by the Belenos-up shows the excellent correlation between the two detectors. Yellow points are the twilight, well visible at the end of two measurement nights.

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 18 Reflection coefficient measurement Data: May-June 2004, 6 events selected Due to low ADC gain and wrong ADC calibration in May only June data are available: 2 surviving events in  t=17 h used to a very preliminary estimation on the reflected light. -background level used -top/bottom units relative normalization applied run no.event no.Log(size)  (°)reflectivity % compatible with tyvec reflectivity and detector acceptance

13/03/2005Alba Cappa - Very High Energy Phenomena in the Universe 19 CONCLUSIONS 2004 campaigns 1970m asl, 200m asl), measured: em component; direct Cherenkov light; 2 events of diffuse Cherenkov light; background evaluation; winter (Grenoble): more statistics, analysis of the events is still in progress; UVscope characterization; spring/summer 2005 (Capo sea level- Sicily): final measurements with UVscope; direct Cherenkov light detection.