| Title: | Telescope Array Composition Summary |
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| Authors: | ID Hanlon, W. (Author)
ID Lundquist, Jon Paul, UNG (Author), et al. |
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| Files: |  ICRC2017_536.pdf (499,33 KB)
MD5: 66F2D51BD2069DB47B3F3B9F8ED4CEB2
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| Language: | English |
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| Work type: | Not categorized |
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| Typology: | 1.08 - Published Scientific Conference Contribution |
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| Organization: | UNG - University of Nova Gorica
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| Abstract: | Ultra high energy cosmic ray (UHECR) chemical composition is
important to resolving questions about the locations of UHECR
sources and propagation models. Because composition can only be
deduced by a process of statistical inference via the observation of air shower maxima (Xmax), UHECR observatories with large data
collection rates must be employed to reduce statistical
fluctuations. Telescope Array (TA), the largest cosmic ray
observatory in the Northern Hemisphere, is designed to answer the
question of UHECR composition, as well as other important features
of cosmic ray flux, by combining a large array of over 500
scintillation surface detectors spread over 700 km^2, and three
fluorescence detector stations overlooking the array. With eight
years of data recorded, results of the measurements of UHECR
composition will be presented. UHECR composition is traditionally
measured by comparing the first and second moments of the
distributions of shower maxima, which evolves with energy, between
data and simulations. Reducing statistical fluctuations in the data
helps to distinguish between different primary elements in the
flux. In the current generation of cosmic ray observatories, UHECR
data sets are large enough, and statistical uncertainties are now
small enough, that we can safely distinguish between very light
primary source flux (i.e., protons) and heavy flux (i.e.,
iron). Reducing systematic uncertainties is also important though,
since large systematic shifts in air shower maxima will influence
the interpretation of the data when compared to models. TA therefore employs different methods of measuring Xmax, including stereo air fluorescence, air fluorescence-surface counter hybrid, and a new technique using only surface counters. Updated results of TA hybrid composition among the different methods are presented using up to eight years of data. Agreement among all TA hybrid composition results are shown as well as detailed systematic errors which can be further explored by comparing composition results of the different measurement methods. Comparison of TA Xmax data are
compared to different composition models as well. |
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| Keywords: | UHECR, Cosmic rays, composition |
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| Publication version: | Version of Record |
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| Year of publishing: | 2018 |
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| Number of pages: | 8 |
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| Numbering: | 301, 301 |
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| PID: | 20.500.12556/RUNG-5170-56b2e543-8935-3d16-5d17-dfd96fdd7ff5  |
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| COBISS.SI-ID: | 13032195 |
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| DOI: | 10.22323/1.301.0536 |
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| NUK URN: | URN:SI:UNG:REP:ONQKBLO6 |
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| Publication date in RUNG: | 29.04.2020 |
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| Views: | 2454 |
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| Downloads: | 83 |
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