Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy

The proposal to use ground based radio telescopes for detection of Askaryan radio pulses from particle cascades arising when extremely high-energy (EHE > 1020 eV) cosmic rays (including neutrinos) interact with the lunar regolith of multi gigaton mass was made at the end of 1980s in the framework...

Full description

Bibliographic Details
Main Authors: Zheleznykh Igor, Dagkesamanskii Rustam, Dedenko Leonid, Dedenko Grigorii
Format: Article
Language:English
Published: EDP Sciences 2017-01-01
Series:EPJ Web of Conferences
Online Access:https://doi.org/10.1051/epjconf/201714511002
id doaj-ca7a2915fa3f4283aabb41cfccd26cc3
record_format Article
spelling doaj-ca7a2915fa3f4283aabb41cfccd26cc32021-08-02T14:26:30ZengEDP SciencesEPJ Web of Conferences2100-014X2017-01-011451100210.1051/epjconf/201714511002epjconf-isvhecri2016_11002Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomyZheleznykh IgorDagkesamanskii Rustam0Dedenko Leonid1Dedenko Grigorii2Lebedev Physics Institute, Russian Academy of SciencesMoscow State UniversityNuclear Research National UniversityThe proposal to use ground based radio telescopes for detection of Askaryan radio pulses from particle cascades arising when extremely high-energy (EHE > 1020 eV) cosmic rays (including neutrinos) interact with the lunar regolith of multi gigaton mass was made at the end of 1980s in the framework of the Russian (Soviet) DUMAND Program. During more than a quarter of century a number of lunar experiments were carried out mainly in the 1–3 GHz frequency range using the large radio telescopes of Australia, USA, Russia and other countries but these experiments only put upper limits to the EHE cosmic rays fluxes. For this reason, it would be of great interest to search for nanosecond radio pulses from the Moon in a wider interval of frequencies (including lower ones of 100–350 MHz) with larger radio detectors – for example the giant radio telescope SKA (Square Kilometer Array) which is constructed in Australia, New Zealand and South Africa. In this paper possibilities are discussed to use one of the most sensitive meter-wavelength (∼ 110 MHz) Large Phased Array (LPA) of 187 × 384 m2 and the wide field of view meter-wavelength array of the Pushchino Radio Astronomy Observatory as prototypes of low frequency radio detectors for lunar experiments. The new scheme for fast simulation of ultrahigh and extremely high-energy cascades in dense media is also suggested. This scheme will be used later for calculations of radio emission of cascades in the lunar regolith with energies up to 1020 eV and higher in the wide frequency band of 0.1− a few GHz.https://doi.org/10.1051/epjconf/201714511002
collection DOAJ
language English
format Article
sources DOAJ
author Zheleznykh Igor
Dagkesamanskii Rustam
Dedenko Leonid
Dedenko Grigorii
spellingShingle Zheleznykh Igor
Dagkesamanskii Rustam
Dedenko Leonid
Dedenko Grigorii
Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
EPJ Web of Conferences
author_facet Zheleznykh Igor
Dagkesamanskii Rustam
Dedenko Leonid
Dedenko Grigorii
author_sort Zheleznykh Igor
title Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
title_short Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
title_full Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
title_fullStr Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
title_full_unstemmed Development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
title_sort development of the radio astronomical method of cosmic particle detection for extremely high-energy cosmic ray physics and neutrino astronomy
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2017-01-01
description The proposal to use ground based radio telescopes for detection of Askaryan radio pulses from particle cascades arising when extremely high-energy (EHE > 1020 eV) cosmic rays (including neutrinos) interact with the lunar regolith of multi gigaton mass was made at the end of 1980s in the framework of the Russian (Soviet) DUMAND Program. During more than a quarter of century a number of lunar experiments were carried out mainly in the 1–3 GHz frequency range using the large radio telescopes of Australia, USA, Russia and other countries but these experiments only put upper limits to the EHE cosmic rays fluxes. For this reason, it would be of great interest to search for nanosecond radio pulses from the Moon in a wider interval of frequencies (including lower ones of 100–350 MHz) with larger radio detectors – for example the giant radio telescope SKA (Square Kilometer Array) which is constructed in Australia, New Zealand and South Africa. In this paper possibilities are discussed to use one of the most sensitive meter-wavelength (∼ 110 MHz) Large Phased Array (LPA) of 187 × 384 m2 and the wide field of view meter-wavelength array of the Pushchino Radio Astronomy Observatory as prototypes of low frequency radio detectors for lunar experiments. The new scheme for fast simulation of ultrahigh and extremely high-energy cascades in dense media is also suggested. This scheme will be used later for calculations of radio emission of cascades in the lunar regolith with energies up to 1020 eV and higher in the wide frequency band of 0.1− a few GHz.
url https://doi.org/10.1051/epjconf/201714511002
work_keys_str_mv AT zheleznykhigor developmentoftheradioastronomicalmethodofcosmicparticledetectionforextremelyhighenergycosmicrayphysicsandneutrinoastronomy
AT dagkesamanskiirustam developmentoftheradioastronomicalmethodofcosmicparticledetectionforextremelyhighenergycosmicrayphysicsandneutrinoastronomy
AT dedenkoleonid developmentoftheradioastronomicalmethodofcosmicparticledetectionforextremelyhighenergycosmicrayphysicsandneutrinoastronomy
AT dedenkogrigorii developmentoftheradioastronomicalmethodofcosmicparticledetectionforextremelyhighenergycosmicrayphysicsandneutrinoastronomy
_version_ 1721231265222361088