Report on Correlation between Radon Outgassing and Aftershocks Activity along the Bam Fault in Kerman Province of Iran

Authors

  • Abdollah Khorshidi Gerash Research Center of Paramedical Sciences, Gerash University of Medical Sciences, P.O. Box: 7441758666, Gerash, Iran. Tehran University of Medical Sciences, Tehran, Iran. Radiation Application Research School, Nuclear Science and Technology Research Institute, Tehran, Iran
  • Jamshid Soltani Nabipour Cellular and Molecular Gerash Research Center, Gerash University of Medical Sciences, P.O. Box: 7441758666, Gerash, Iran.

DOI:

https://doi.org/10.15392/bjrs.v5i2.266

Keywords:

Radon, earthquake prediction, Bam, meteorological parameters, AlphaGurad, aftershocks.

Abstract

After the Earthquake in Bam in December 26, 2003, a team was dispatched to this area to monitor the relationship between Variation in the Radon (222Rn) concentration and the magnitude of aftershocks. Meteorological parameters such as air pressure, temperature and humidity were measured. Radon concentration at depth of 90 cm of soil was also measured using AlphaGuard (Model 2000PRO) in 10 minutes periods. The measurement site was near the fault location and the radon concentration was systemically measured for a period of three months. A correlation between radon concentration and the available aftershocks data is discussed. More than 150 small to moderate aftershocks with a magnitude ranging from M=2.1 to 6.5 in scale of Richter occurred in the region during the period of this study at the various distances (below 20 km of epicenter) from the radon monitoring sites. When the magnitude of aftershocks increased, variation of radon concentration could be seen more clearly.

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References

Irk, HS.; Sharma, AK.; Walia, V. Correlation of alpha-logger radon data with microseismicity in N-W Himalaya. Curr Sci, v. 72, p. 656-663, 1997.

Segovia, N.; Mena, M.; Monnin, M.; Pena, P.; Seidel, JL.; Tamez, E. Radon-in-soil variations related to volcanic activity. Radiat Meas, v. 28, p.745-750, 1997.

Segovia, N.; Mena, M.; Pena, P.; Tamez, E.; Seidel, JL.; Monnin, M.; Valdes, C. Soil radon time series: surveys in seismic and volcanic areas. Radiat Meas, v. 31, p. 307-312, 1999.

Zmazek, B.; Vaupotic, J.; Zivcic, M.; Premru, U.; Kobal, I. Radon monitoring for earthquake prediction in Slovenia. Fizika B, v. 9, p. 111-118, 2000.

Zmazek, B.; Todorovski, L.; Dzeroski, S.; Vaupotic, J.; Kobal, I. Application of decision trees to the analysis of soil radon data for earthquake prediction. Appl Radiat Isot, v. 58, p. 697-706, 2003.

Outkin, VI.; Yurkov, AK.; Krivasheev, SV. Dynamics of radon concentration in soil for predicting earthquakes, In: Proc 3rd Eurosymp on protection against Radon, 2001, p. 137-141.

Steinitz, G.; Begin, ZB.; Gazit-Yaari, N. Statistically significant relation between Rn Flux and weak Earthquakes in the Dead sea Rift Valley. Geology, v. 31, p. 505-508, 2003.

Yakovleva; VS. A theoretical method for estimating the characteristics of radon transport in homogeneous soil. Ann Geophys, v. 48, p. 195-198, 2005.

Fleischer, RL. Radon and earthquake prediction: Radon Measurements by Etched Track Detectors: Applications in Radiation Protection, Earth Sciences, and Environment. Eds SA Durrani and R Ilic. Singapore: World Scientific, 1997. p. 285-299.

Inceoz, M.; Baykara, O.; Aksoy E.; Dogru, M. Measurements of soil gas radon in active fault systems: A case study along the North and East anatolian fault systems in Turkey. Radiat Meas, v. 41, p. 349–353, 2006.

Singh, M.; Kumar, M.; Jain, RK.; Chatrath, RP. Radon in ground water related to seismic events. Radiat Meas, v. 30, p. 465–469, 1999.

Bunzl, K.; Ruckerbauer, F.; Winkler, R. Temporal and small scale spatial variability of 222Rn gas in a soil with a high gravel content. Sci Total Environ, v. 220, p. 157–166, 1998.

Winkler, R.; Ruckerbauer, F.; Bunzl, K. Radon concentration in soil gas: a comparison of the variability resulting from different methods, spatial heterogeneity and seasonal fluctuations. Sci Total Environ, v. 272, p. 273–282, 2001.

Negarestani, A.; Setayeshi, S. Ghannadi-Maragheh M, Akashe B. Layered neural networks based on analysis of radon concentration and environmental parameters in earthquake prediction. J Environ Radioactiv, v. 62, p. 225-233, 2001.

Iakovleva, VS.; Ryzhakova, NK. Spatial and temporal variations of radon concentration in soil air. Radiat Meas, v. 36, p. 385-388, 2003.

Yakovleva, VS.; Karataev, VD. Radon flux density at the Earth’s surface as a possible indicator of the stress and strain state of the geological environment. J Volcanol Seismol, v. 1, p. 67-70, 2007.

Planinic, J.; Radolic, V.; Culo, D. Searching for an earthquake precursor: Temporal Variations of Radon in Soil and Water. Fizika B, v. 9, p. 75-82, 2000.

International Atomic Energy Agency. Isotopic and geochemical precursors of earthquakes and volcanic eruptions. IAEA-TECDOC-726. Vienna: IAEA, 1993.

Mostafazadeh, M.; Farahbod, AM.; Mokhtari, M.; Allamehzadeh, M. Seismological Aspect of 26 December 2003 Bam earthquake. J Seismic Earthq Eng, v. 5, p. 15-21, 2004.

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Published

2017-07-19

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Articles

How to Cite

Report on Correlation between Radon Outgassing and Aftershocks Activity along the Bam Fault in Kerman Province of Iran. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 5, n. 2, 2017. DOI: 10.15392/bjrs.v5i2.266. Disponível em: https://bjrs.org.br/revista/index.php/REVISTA/article/view/266.. Acesso em: 22 nov. 2024.

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