Radon signals at the Roded site, Southern Israel

Steinitz, G.; Piatibratova, Oksana

doi:10.5194/se-1-99-2010

Cited by 18 publications

(19 citation statements)

References 25 publications

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“…The measured signal was decomposed using a 25-h sliding average revealing two types of signals in the radon time series-daily radon (DR) signals and MD signals, similar to those encountered in several other sites and locations [15][16][17]25]. The MD signals, with amplitudes of over 10 kcounts/15-min, span 2 or more days and are non-periodic.…”

Section: Resultsmentioning

confidence: 99%

“…Geophysical analysis of these relatively long time series measured with a high time resolution (within 1 h) demonstrates that Rn signals in air confined within rock units are characterized by systematic recurrence of signal patterns in the temporal, geological and geographical domains, at a depth of more than 100 m. The main types recognized are multi-year, annual radon (AR; periodic), MD and daily radon (DR; periodic) signals [14,15,25,34] as well as intense variation lasting several hours [16,17]. Examination of the patterns suggested that -variation patterns in the subsurface regime cannot be accounted for by simple and direct time varying processes in the gas system such as emanation, diffusion, absorption and advection; -absence of above surface atmospheric influence, in particular pressure; and -periodicity in the DR signal is characterized by solar tide frequencies S1 (24-h), S2 (12-h) and S3 (8-h) [31], implying an external above surface driving mechanism.…”

Section: Discussionmentioning

confidence: 99%

“…At these levels, the air pressure regime is related to the local atmospheric barometric pressure while temperature tends to show stabile patterns reflecting the rock temperature at depth. Radon signals characterized by systematical recurrence of patterns in the temporal, geological and geographical domains have been reported from tunnels and boreholes in France [10], from Tenerife at a depth of more than 800 m [11][12][13] and from the desert in Israel at a depth of more than 100 m [14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

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Influence of a component of solar irradiance on radon signals at 1 km depth, Gran Sasso, Italy

2013

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Exploratory monitoring of radon is conducted at one location in the deep underground Gran Sasso National Laboratory (LNGS). Measurements (15-min resolution) are performed over a time span of ca 600 days in the air of the surrounding calcareous country rock. Using both α - and γ -ray detectors, systematic and recurring radon signals are recorded. Two primary signal types are determined: (i) non-periodic multi-day (MD) signals lasting 2–10 days and (ii) daily radon (DR) signals—which are of a periodic nature exhibiting a primary 24-h cycle ( θ =0.48). The local ancillary environmental conditions (pressure, temperature) seem not to affect radon in air monitored at the site. Long-term patterns of daytime measurements are different from the pattern of night-time measurements indicating a day–night modulation of γ -radiation from radon in air. The phenomenology of the MD and DR signals is similar to situations encountered at other locations where radon is monitored with a high time resolution in geogas at upper crustal levels. In accordance with recent field and experimental results, it is suggested that a component of solar irradiance is affecting the radiation from radon in air, and this influence is further modulated by the diurnal rotation of the Earth. The occurrence of these radon signals in the 1 km deep low-radiation underground geological environment of LNGS provides new information on the time variation of the local radiation environment. The observations and results place the LNGS facility as a high-priority location for performing advanced investigations of these geophysical phenomena.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Influence of a component of solar irradiance on radon signals at 1 km depth, Gran Sasso, Italy

2013

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“…Thus, the amount of radon exhalation depends on the elastic properties and porosity of the rocks and on the local fracture system (e.g. Holub and Brady, 1981;Kies et al, 2002Kies et al, , 2005Vaupoti c et al, 2010) and shows large temporal variations due to meteorological and hydrological effects (Garavaglia et al, 1999;Vargas and Ortega, 2006;Papp et al, 2008;Smetanova et al, 2010;Steinitz and Piatibratova, 2010;Szab o et al, 2013). Analysis of temporal variations in the radon gas concentration is a useful tool to study geodynamic processes associated with tectonic (Garavaglia et al, 1998Aumento, 2002;Omori et al, 2007;Mahajan et al, 2010;Utkin and Yurkov, 2010) and volcanic (Toutain and Baubron, 1999;Viñas et al, 2007) activities as well as in looking for a warning sign for earthquakes (Igarashi et al, 1995;Yong and Wei, 1995;Garavaglia et al, 1999;Virk et al, 2000;Crockett et al, 2006;Kawada et al, 2007;Inan et al, 2008;Yasuoka et al, 2009;Crockett and Gillmore, 2010;Cigoliní et al, 2015).…”

Section: Introductionmentioning

confidence: 97%

“…Radon gas, which is continuously produced in rocks and soils, migrates into the air. The migration is mainly affected by convection and molecular diffusion (Steinitz and Piatibratova, 2010;Szab o et al, 2013). Thus, the amount of radon exhalation depends on the elastic properties and porosity of the rocks and on the local fracture system (e.g.…”

Section: Introductionmentioning

confidence: 99%

Investigation of temperature and barometric pressure variation effects on radon concentration in the Sopronbánfalva Geodynamic Observatory, Hungary

Mentes

Eper-Pápai

2015

Journal of Environmental Radioactivity

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Radon concentration variation has been monitored since 2009 in the artificial gallery of the Sopronbánfalva Geodynamic Observatory, Hungary. In the observatory, the radon concentration is extremely high, 100 -600 kBq m-3 in summer and some kBq m-3 in winter. The relationships between radon concentration, temperature and barometric pressure were separately investigated in the summer and winter months by Fast Fourier Transform, Principal Component Analysis, Multivariable Regression and Partial Least Square analyses in different frequency bands. It was revealed that the long-period radon concentration variation is mainly governed by the temperature (20 kBq m-1 °C-1) both in summer and winter. The regression coefficients between long-period radon concentration and barometric pressure are -1.5 KBq m-3 hPa-1 in the summer and 5 KBq m-3 hPa-1 in the winter months. In the 0.072-0.48 cpd frequency band the effect of the temperature is about -1 kBq m-3 °C-1 and that of the barometric pressure is -5 KBq m-3 hPa-1 in summer and -0.5 KBq m-3 hPa-1 in winter. In the high frequency range (> 0.48 cpd) all regression coefficients are one order of magnitude smaller than in the range of 0.072-0.48 cpd. Fast Fourier Transform of the radon concentration, temperature and barometric pressure time series revealed S1, K1, P1, S2, K2, M2 tidal constituents in the data and week O1 components in the radon concentration and barometric pressure series. A detailed tidal analysis, however, showed that the radon tidal components are not directly driven by the gravitational force but rather by solar radiation and barometric tide. Principal Component Analysis of the raw data was performed to investigate the yearly, summer and winter variability of the radon concentration, temperature and barometric pressure. In the summer and winter periods the variability does not change. The higher variability of the radon concentration compared to the variability of the temperature and the barometric pressure shows that besides the temperature and barometric pressure variations other agents, e.g. natural ventilation of the observatory, wind, etc. also play an important role in the radon concentration variation. Sopronbánfalva Geodynamic Observatory, Hungary. In the observatory, the radon 7 concentration is extremely high, 100 -600 kBq m -3 in summer and some kBq m -3 in winter. 8The relationships between radon concentration, temperature and barometric pressure were

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Indications for non-terrestrial influences on radon signals from a multi-year enhanced confined experiment

Steinitz¹,

Sturrock²,

Fischbach³

et al. 2018

Preprint

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Radon signals at the Roded site, Southern Israel

Cited by 18 publications

References 25 publications

Influence of a component of solar irradiance on radon signals at 1 km depth, Gran Sasso, Italy

Influence of a component of solar irradiance on radon signals at 1 km depth, Gran Sasso, Italy

Investigation of temperature and barometric pressure variation effects on radon concentration in the Sopronbánfalva Geodynamic Observatory, Hungary

Indications for non-terrestrial influences on radon signals from a multi-year enhanced confined experiment

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