Study of Performance Improvement for Air Shower Array with Surface Water Cherenkov Detectors

Similar documents
Accurate Measurement of the Cosmic Ray Proton Spectrum from 100TeV to 10PeV with LHAASO

The overview and current status of the ALPACA experiment

PoS(ICRC2015)424. YAC sensitivity for measuring the light-component spectrum of primary cosmic rays at the knee energies

Primary cosmic ray mass composition above 1 PeV as measured by the PRISMA-YBJ array

PoS(ICRC2015)432. Simulation Study On High Energy Electron and Gamma-ray Detection With the Newly Upgraded Tibet ASgamma Experiment

Timing calibration of the LHAASO-KM2A electromagnetic particle detectors

PoS(ICRC2015)430. Shower reconstruction performance of the new Tibet hybrid experiment consisting of YAC-II, Tibet-III and MD arrays

PoS(ICRC2015)1001. Gamma Hadron Separation using Pairwise Compactness Method with HAWC

Gamma/Proton separation study for the LHAASO-WCDA detector

Measurement of the Solar Magnetic Field effect on cosmic rays using the Sun shadow observed by the ARGO-YBJ experiment

Gamma-Ray Astronomy with a Wide Field of View detector operated at Extreme Altitude in the Southern Hemisphere.

arxiv: v1 [astro-ph.im] 14 Sep 2017

A Monte Carlo simulation study for cosmic-ray chemical composition measurement with Cherenkov Telescope Array

Antifreeze design for Muon Detector of LHAASO

Long-term stability plastic scintillation for LHAASO-KM2A

PoS(ICRC2015)635. The NICHE Array: Status and Plans. Douglas R Bergman

PoS(ICRC2017)945. In-ice self-veto techniques for IceCube-Gen2. The IceCube-Gen2 Collaboration

Longitudinal profile of Nµ/Ne in extensive air showers: Implications for cosmic rays mass composition study

Measurement of the CR e+/e- ratio with ground-based instruments

Measurement of the cosmic ray spectrum and chemical composition in the ev energy range

Muon track reconstruction and veto performance with D-Egg sensor for IceCube-Gen2

PoS(EPS-HEP2017)008. Status of the KM3NeT/ARCA telescope

PoS(ICRC2017)326. The influence of weather effects on the reconstruction of extensive air showers at the Pierre Auger Observatory

The Cosmic Ray Air Fluorescence Fresnel lens Telescope (CRAFFT) for the next generation UHECR observatory

HAWC Observation of Supernova Remnants and Pulsar Wind Nebulae

CORSIKA modification for electric field simulations on pions, kaons and muons

Neutron flux measurement using fast-neutron activation of 12 B and 12 N isotopes in hydrocarbonate scintillators

Air Shower Measurements from PeV to EeV

Mass Composition Study at the Pierre Auger Observatory

Primary CR Energy Spectrum and Mass Composition by the Data of Tunka-133 Array. by the Tunka-133 Collaboration

Development of Analysis Method using GEANT4 for Cosmic Ray Radiography

arxiv: v1 [astro-ph.im] 13 Sep 2017 Julian Sitarek University of Łódź, PL Lodz, Poland

Measurement of High Energy Neutrino Nucleon Cross Section and Astrophysical Neutrino Flux Anisotropy Study of Cascade Channel with IceCube

Latest news from the High Altitude Water Cherenkov Observatory

Muon track reconstruction and veto performance with D-Egg sensor for IceCube-Gen2

Parameters Sensitive to the Mass Composition of Cosmic Rays and Their Application at the Pierre Auger Observatory

EAS lateral distribution measured by analog readout and digital readout of ARGO-YBJ experiment

The cosmic rays web monitor of the LAGO project

The KASCADE-Grande Experiment

Probing QCD approach to thermal equilibrium with ultrahigh energy cosmic rays

HAWC and the cosmic ray quest

Performance of the MAGIC telescopes under moonlight

Zero degree neutron energy spectra measured by LHCf at s = 13 TeV proton-proton collision

arxiv: v1 [astro-ph.he] 19 Oct 2017

Measurement of nuclear recoil responses of NaI(Tl) crystal for dark matter search

PoS(ICRC2017)031. Interplanetary Coronal Mass Ejection and the Sun s Shadow Observed by the Tibet Air Shower Array

arxiv: v1 [astro-ph.im] 1 Sep 2015

EAS spectrum in thermal neutrons measured with PRISMA-32

PoS(ICRC2017)750. Detection of vertical muons with the HAWC water Cherenkov detectors and it s application to gamma/hadron discrimination

Latest results and perspectives of the KASCADE-Grande EAS facility

Calibration of large water-cherenkov Detector at the Sierra Negra site of LAGO

Observations with the Mini Neutron Monitor at Sierra Negra, Mexico

The cosmic ray energy spectrum measured using the Pierre Auger Observatory

AugerPrime. Primary cosmic ray identification for the next 10 years. Radomír Šmída.

Ultra-High-Energy Cosmic Rays: A Tale of Two Observatories

The cosmic-ray energy spectrum above ev measured with the LOFAR Radboud Air Shower Array

7 th International Workshop on New Worlds in Astroparticle Physics São Tomé, September 2009 THE AMIGA PROJECT

Observations of the Crab Nebula with Early HAWC Data

PoS(ICRC2017)775. The performance of DAMPE for γ-ray detection

A Galaxy in VHE Gamma-rays: Observations of the Galactic Plane with the H.E.S.S. array

Measurements of Heavy Nuclei with the CALET Experiment

Measurement of the Cosmic Ray Energy Spectrum with ARGO-YBJ

From the Knee to the toes: The challenge of cosmic-ray composition

DIFFERENT H.E. INTERACTION MODELS

Study of muon bundles from extensive air showers with the ALICE detector at CERN LHC

Cosmic Rays. Discovered in 1912 by Viktor Hess using electroscopes to measure ionization at altitudes via balloon

Variable atmospheric transparency studies for the MAGIC telescopes

PoS(ICRC2017)816. Light-Trap: A SiPM Upgrade for Very High Energy Astronomy and Beyond

Dependence of the GRAPES-3 EAS particle density and trigger rate on atmospheric pressure and temperature

LAGO Ecuador, Implementing a set of WCD detectors for Space Weather research: first results and further developments

Bright gamma-ray sources observed by DArk Matter Particle Explorer

Study of high muon multiplicity cosmic-ray events with ALICE at the CERN Large Hadron Collider

Status KASCADE-Grande. April 2007 Aspen workshop on cosmic ray physics Andreas Haungs 1

PoS(ICRC2017)765. Towards a 3D analysis in Cherenkov γ-ray astronomy

Depth of maximum of air-shower profiles at the Pierre Auger Observatory: Measurements above ev and Composition Implications

The NUCLEON Space Experiment Preliminary Results. Skobeltsyn Institute of Nuclear Physics, Moscow State University, Moscow, , Russia

High-Energy Particle Showers in Coincidence with Downward Lightning Leaders at the Telescope Array Cosmic Ray Observatory

PoS(EPS-HEP2017)074. Darkside Status and Prospects. Charles Jeff Martoff Temple University

A Template-based γ-ray Reconstruction Method for Air Shower Arrays

Determination of parameters of cascade showers in the water calorimeter using 3D-distribution of Cherenkov light

PoS(NOW2016)041. IceCube and High Energy Neutrinos. J. Kiryluk (for the IceCube Collaboration)

GRAINE Project: a balloon-borne emulsion gamma-ray telescope

First Light with the HAWC Gamma-Ray Observatory

A Summary of recent Updates in the Search for Cosmic Ray Sources using the IceCube Detector

arxiv: v1 [astro-ph.im] 25 Mar 2015

On the Combined Analysis of Muon Shower Size and Depth of Shower Maximum

Studies of Ultra High Energy Cosmic Rays with the Pierre Auger Observatory

Improving H.E.S.S. cosmic-ray background rejection by means of a new Gamma-Ray Air Shower Parametrisation (GRASP)

The air-shower experiment KASCADE-Grande

Hadronic Interaction Studies with ARGO-YBJ

A SEARCH FOR ASTROPHYSICAL POINT SOURCES OF 100 TEV GAMMA RAYS BY THE UMC COLLABORATION

Study of Solar Gamma Rays basing on Geant4 code

VHE Gamma-Ray Future Project: Beyond CANGAROO

Water Cherenkov Detector installation by the Vertical Muon Equivalent technique

arxiv: v1 [astro-ph] 26 Apr 2007

GRAINE balloon-borne experiment in 2015 : Observations with a high angular resolution gamma-ray telescope

arxiv: v1 [astro-ph.he] 28 Jan 2013

The TAIGA experiment - a hybrid detector for very high energy gamma-ray astronomy and cosmic ray physics in the Tunka valley

Solar Event Simulations using the HAWC Scaler System

Search for a diffuse cosmic neutrino flux with ANTARES using track and cascade events

Transcription:

Study of Performance Improvement for Air Shower Array with Surface Water Cherenkov Detectors, a K. Hibino, b T. K. Sako, cd T. Asaba, e Y. Katayose e and M. Ohnishi c a College of Industrial Technology, Nihon University, Japan b Faculty of Engineering, Kanagawa University, Japan c Institute for Cosmic Ray Research, University of Tokyo, Japan d Escuela de Ciencias Físicas y Nanotechnología, Yachay Tech, Ecuador e Faculty of Engineering, Yokohama National University, Japan E-mail: shiomi.atsushi@nihon-u.ac.jp Unlike Imaging Atmospheric Cherenkov Telescopes (IACTs), Extensive Air Shower (EAS) arrays can observe cosmic rays with wide fields of view of about 2 sr and with duty cycles of almost 24 hours every day regardless of weather conditions or the moonlight. Some EAS arrays are located at high altitudes to lower their observation thresholds of cosmic rays and successfully observe gamma rays in the range of several TeV. However, sensitivity of EAS arrays is not as good as IACT mainly because the angular resolution of EAS arrays is poor. In this paper, we report the progress of performance study of an EAS array of scintillation detectors with surface water Cherenkov detectors (WCDs) for improving its angular resolution. 35th International Cosmic Ray Conference ICRC2017-10-20 July, 2017 Bexco, Busan, Korea Speaker. c Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0). http://pos.sissa.it/

1. Introduction Cosmic rays up to the knee region are theoretically considered to be accelerated by supernova remnants in our galaxy. Gamma rays from π 0 decays produced by cosmic rays interacting with interstellar matter near the acceleration sites may be observed up to the 100 TeV region. Therefore, observation of 100 TeV region gamma rays is important for searching origins of cosmic rays. As an experiment currently in operation, there is a possibility that a hybrid experiment of an EAS array of scintillation detectors and muon detectors such as the Tibet ASγ experiment will open an observation window for the 100 TeV region gamma rays[1]. One of the merits of EAS arrays is that they can directly observe the secondary particles regardless of day and night, and can always observe the wide fields of view about 2 sr, which means EAS arrays having such characteristics are more advantageous than IACTs in the low flux of gamma rays expected in 100 TeV region. However, the angular resolution of EAS arrays such as Tibet array is about 0.2 degrees for 100 TeV gamma rays [1], and the angular resolution of < 0.1 degrees above at 10 TeV or more has not been achieved, so it is a point to be improved. It is also important to be able to investigate more detailed structures of spreading sources. In order to improve angular resolution, it is necessary to increase the filling ratio of detectors and to determine the shower front more accurately by sampling more time information of secondary particles. By simply placing scintillation detectors at a filling ratio of nearly 10%, it will be considered possible to reach nearly 0.05 degrees at 100 TeV by simulation, but this is costly. WCDs would have ambiguity about particle density and time information as compared to scintillation detectors. However, its effective area is easy to widen, and it is also sensitive not only to secondary electrons but also to secondary gamma rays. Furthermore, since it is possible to increase the filling ratio of detectors at lower cost, it is promising. A scintillation detector capable of accurately measuring secondary particles samples a part of the longitudinal development of extensive air showers, and the accuracy of energy determination can be about 15% in the 100 TeV region by EAS array [2], and combining the both detectors will make it possible to observe the energy spectrum of gamma rays more accurately. By exploiting the advantages of the both, we will study how far we can improve the angular resolution by experiments of water Cherenkov detectors, based on simulation and prototype detectors. 2. Simulation We have assumed the array of 36 WCDs arranged at 45 m intervals built at an altitude of 4700m a.s.l.. Each WCD consists of a cylinder tank in a diameter of 8.0 m and variable in height, with a maximum of 13 units, 8 or (virtually) 16 inch PMTs arranged as shown in figure 1 and 2. Air showers are generated with the Corsika Ver.7.4 code [3], using QGSJET-II-04 and GHEISHA as a hadronic interaction model. Primary gamma rays are vertically generated at 10 TeV aimed to the center of the array. The number of generated air showers is 10 3. After simulating the response of the WCD array for the air showers with the GEANT4.10.02 [4], we obtain the detection efficiency and will obtain the estimated arrival direction in the next step. In this simulation, the maximum quantum efficiency of PMTs is set to 20%. For WCD, it was confirmed that the light intensity reached its maximum at the depth of 1.5 m (from the top of PMTs). 1

Figure 1: Schematic view of the water Cherenkov detector array. Enclosed by the dashed line is the area of assumed air shower and muon detector array. Gamma rays are vertically injected to the center of the array in this simulation. 3. Results and Discussion Figure 2: Schematic view of a WCD. WCD is made of a 3.0 mm-thick stainless steel water tank of 8.0 m diameter. The water level can be changed, and one or 13 upward-facing 8 inch ϕ or (virtually) 16 inch ϕ PMTs are installed on the floor. In this simulation, we explain the detection efficiency of WCDs at the depth of 1.1 m (from the top of PMTs). We investigate the detection efficiency for the case of one PMT in the center, three near the center, seven around the center, and 13 PMTs in the WCD. Figure 3: The detection efficiency as a function of the distance between each WCD center and shower core. Trigger condition is any one of PMTs ( 3 p.e.) in any WCD. In figure 3, it can be seen that when the distance from the shower core to the center of WCDs is 80 m or more, the detection efficiency of WCDs is greatly reduced, and it changes with the number and sizes of the PMTs. Figure 4 shows the detection efficiency as a function of the sum 2

of all photosensitive areas of PMTs in a WCD (left) and the ratio of number of triggered WCDs in case of 16" PMTs (right). The trigger condition is any one of PMTs ( 3 p.e.) in any WCD. And the case where the trigger condition is any three of PMTs ( 3 p.e.) in any one WCD is shown in figure 5. It is understood that the detection efficiency correlates with total photosensitive areas in a WCD. Naturally, when the trigger condition is changed from any one to any three, the probability increases as the number of PMTs increases, so the detection efficiency increases as the number of PMTs increases even in the same photosensitive area. When seven 16 inch PMTs were set in a WCD, it was found that more than 27 WCDs out of 36 detect about 90% of vertical 10 TeV gamma rays under trigger conditions at any one of PMTs in each WCD. Under trigger condition at any three of PMTs in each WCD, it was found that more than 16 WCDs out of 36 detect about 90% of vertical 10 TeV gamma rays. Figure 4: Left: The detection efficiency as a function of the sum of all photosensitive areas of PMTs in a WCD. Right: The ratio of number of triggered WCDs in case of 16 inch PMT. Trigger condition is any one of PMTs ( 3 p.e.) in any one WCD. Figure 5: Left: The detection efficiency as a function of the sum of all photosensitive areas of PMTs in a WCD. Right: The ratio of number of triggered WCDs in case of 16 inch PMT. Trigger condition is any three of PMTs ( 3 p.e.) in any one WCD. 3

In the future, we will investigate the response of a prototype WCD, develop the direction determination algorithm, determine the angular resolution, and explore how angular resolution changes depending on depth, WCD and PMT arrangement, etc. Acknowledgments This work was supported by JSPS KAKENHI Grant Number JP15K05108. References [1] T.K. Sako, et al. Exploration of a 100 TeV gamma-ray northern sky using the Tibet air-shower array combined with an underground water-cherenkov muon-detector array, Astroparticle Physics, 32 177 (2009) [2] K. Kawata, et al. Energy determination of gamma-ray induced air showers observed by an extensive air shower array, Experimental Astronomy, DOI 10.1007/s10686-017-9530-9 (2017) [3] D. Heck et al., CORSIKA: A Monte Carlo Code to Simulate Extensive Air Showers, Report FZKA, 6019, Forschungszentrum Karlsruhe (1998) [4] S. Agostinelli, et al. GEANT4 - a simulation toolkit, Nucl. Instrum. Methods Phys. Res. A, 506 250 (2003) 4

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback