Analysis of atmospheric pressure and temperature effects on cosmic ray measurements

Mendonça, R. R. S.; Raulin, J. P.; Echer, E.; Махмутов, В. С.; Fernandez, G.

doi:10.1029/2012ja018026

Cited by 59 publications

(46 citation statements)

References 27 publications

(31 reference statements)

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“…It can be seen that the number of cosmic ray muons is reduced as the temperature increases. This anti-correlation between the two variables is in agreement with the previously published results of several researchers [6][7]. The decrease in the muon rate as the temperature increases is due to changes in the atmospheric density, which in turn depends on atmospheric temperature.…”

Section: Temperature Effectsupporting

confidence: 81%

“…The rate of the cosmic ray muons due to changes in a meteorological variable x, can be determined experimentally by [6][7]:…”

Section: Instrumentation and Methodsmentioning

confidence: 99%

“…At the detection level, the majority of the observed particles are muons. Their rate depends on several meteorological factors such as the atmospheric pressure, temperature, and the height of the pion production level (height of the first interaction); see for example [4][5][6][7]. Several investigations have shown that the variations in the atmospheric variables' coefficients depend on different factors, such as the type of detected particle and the cutoff rigidity of the considered site [8][9].…”

Section: Introductionmentioning

confidence: 99%

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The Effect of Some Meteorological Parameters on the Cosmic Ray Muons detected by KACST detector

Maghrabi¹,

Aldosary²

2017

Proceedings of 35th International Cosmic Ray Conference — PoS(ICRC2017)

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To study the cosmic ray modulation properly, it is important to remove atmospheric effects. In this study cosmic ray data from the KACST detector in Riyadh, Saudi Arabia (Rc = 14.4 GV), for the period 2007-2009, were used to study the effect of some meteorological parameters on cosmic ray muons. The parameters of interest are the atmospheric pressure, temperature, and relative humidity. We have found that the atmospheric pressure and temperature are inversely correlated with the muon rate. On the other hand, the relative humidity is correlated with the number of cosmic ray muons.

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Section: Temperature Effectsupporting

confidence: 81%

“…The rate of the cosmic ray muons due to changes in a meteorological variable x, can be determined experimentally by [6][7]:…”

Section: Instrumentation and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The Effect of Some Meteorological Parameters on the Cosmic Ray Muons detected by KACST detector

Maghrabi¹,

Aldosary²

2017

Proceedings of 35th International Cosmic Ray Conference — PoS(ICRC2017)

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“…There are many methods of analyzing and removing the temperature effect from cosmic ray intensity observed by ground muon detectors. The simplest methods consist of the comparison of the cosmic ray intensity with: surface temperature changes, the variation of the altitude of maximum muon production (MMP), or the temperature variation at this altitude (Blackett 1938;Hess 1940;Duperier 1949;Trefall 1955a;French & Chasson 1959;Okazaki et al 2008;De Mendonça et al 2013). There are also methods that consider the temperature variation along the entire atmosphere through empirical or theoretical analyses (Sagisaka 1986;Dorman 2004;Berkova et al 2011;De Mendonça et al 2013).…”

Section: Introductionmentioning

confidence: 99%

The Temperature Effect in Secondary Cosmic Rays (Muons) Observed at the Ground: Analysis of the Global Muon Detector Network Data

Mendonça

Braga

Echer

et al. 2016

ApJ

Self Cite

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The analysis of cosmic ray intensity variation seen by muon detectors at Earthʼs surface can help us to understand astrophysical, solar, interplanetary and geomagnetic phenomena. However, before comparing cosmic ray intensity variations with extraterrestrial phenomena, it is necessary to take into account atmospheric effects such as the temperature effect. In this work, we analyzed this effect on the Global Muon Detector Network (GMDN), which is composed of four ground-based detectors, two in the northern hemisphere and two in the southern hemisphere. In general, we found a higher temperature influence on detectors located in the northern hemisphere. Besides that, we noticed that the seasonal temperature variation observed at the ground and at the altitude of maximum muon production are in antiphase for all GMDN locations (low-latitude regions). In this way, contrary to what is expected in high-latitude regions, the ground muon intensity decrease occurring during summertime would be related to both parts of the temperature effect (the negative and the positive). We analyzed several methods to describe the temperature effect on cosmic ray intensity. We found that the mass weighted method is the one that best reproduces the seasonal cosmic ray variation observed by the GMDN detectors and allows the highest correlation with long-term variation of the cosmic ray intensity seen by neutron monitors.

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“…The change in the atmospheric pressure and temperature can produces a significant variations in ground based observations. Thus, it is necessary to take an account of these local effects to get better measurements of shower parameters [1]. As expected, at Ooty, the diurnal variations and semi-diurnal periodicity is seen in temperature and pressure respectively (as shown in Fig.…”

Section: Introductionmentioning

confidence: 98%

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

Zuberi¹,

Ahmad²,

Arunbabu³

et al. 2017

Proceedings of 35th International Cosmic Ray Conference — PoS(ICRC2017)

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The GRAPES-3 experiment, a high density extensive air shower (EAS) array located at Ooty, India is designed for high precision measurements of cosmic ray energy spectrum and nuclear composition in energy range of 10 13 -10 16 eV . It consists of tightly packed 1 m 2 area 400 plastic scintillation detectors covering an effective area of 25,000 m 2 . The trigger rate and particle density measured by EAS array shows strong correlation with the atmospheric parameters such as the pressure, and temperature. By employing linear regression, and Fast Fourier Transform techniques, the pressure and temperature coefficients for the dependence of trigger rate and particle density, respectively were obtained. Thereafter, by applying corrections for these effects the contribution of atmospheric effects was largely eliminated in the EAS data. These corrections are expected to result in a better measurement of EAS parameters which will be presented during the conference.

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Analysis of atmospheric pressure and temperature effects on cosmic ray measurements

Cited by 59 publications

References 27 publications

The Effect of Some Meteorological Parameters on the Cosmic Ray Muons detected by KACST detector

The Effect of Some Meteorological Parameters on the Cosmic Ray Muons detected by KACST detector

The Temperature Effect in Secondary Cosmic Rays (Muons) Observed at the Ground: Analysis of the Global Muon Detector Network Data

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

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