Daily variation of radon gas and its short-lived progeny concentration near ground level and estimation of aerosol residence time

doi:10.1088/1674-1056/25/5/050701

Abstract Atmospheric concentrations of radon (²²²Rn) gas and its short-lived progenies ²¹⁸Po, ²¹⁴Pb, and ²¹⁴Po were continuously monitored every four hours at the ground level in Jeddah city, Kingdom of Saudi Arabia. The measurements were performed three times every week, starting from November 2014 to October 2015. A method of electrostatic precipitation of positively charged ²¹⁸Po and ²¹⁴Po by a positive voltage was applied for determining ²²²Rn gas concentration. The short-lived ²²²Rn progeny concentration was determined by using a filter holder connected with the alpha-spectrometric technique. The meteorological parameters (relative air humidity, air temperature, and wind speed) were determined during the measurements of ²²²Rn and its progeny concentrations. ²²²Rn gas as well as its short-lived progeny concentration display a daily and seasonal variation with high values in the night and early morning hours as compared to low values at noon and in the afternoon. The observed monthly atmospheric concentrations showed a seasonal trend with the highest values in the autumn/winter season and the lowest values in the spring/summer season. Moreover, and in parallel with alpha-spectrometric measurements, a single filter-holder was used to collect air samples. The deposited activities of ²¹⁴Pb and the long-lived ²²²Rn daughter ²¹⁰Pb on the filter were measured with the gamma spectrometric technique. The measured activity concentrations of ²¹⁴Pb by both techniques were found to be relatively equal largely. The highest mean seasonally activity concentrations of ²¹⁰Pb were observed in the autumn/winter season while the lowest mean were observed in the spring/summer season. The mean residence time (MRT) of aerosol particles in the atmospheric air could be estimated from the activity ratios of ²¹⁰Pb/²¹⁴Pb.

Keywords: daily variation radon progeny concentration meteorological variables

Received: 26 November 2015
Revised: 02 January 2016
Accepted manuscript online:

PACS:	07.88.+y	(Instruments for environmental pollution measurements)
	06.90.+v	(Other topics in metrology, measurements, and laboratory procedures)
	23.90.+w	(Other topics in radioactive decay and in-beam spectroscopy)
	92.05.Df	(Climate and inter-annual variability)

Fund: Project supported by the Deanship of Scientific Research (DSR), King Abdulaziz University, Jeddah (Grant No. 291/965/1434).

Corresponding Authors: M Mohery
E-mail: mmohery@hotmail.com,mohery@yahoo.com,mmohery@kau.edu.sa

Cite this article:

M Mohery, A M Abdallah, A Ali, S S Baz Daily variation of radon gas and its short-lived progeny concentration near ground level and estimation of aerosol residence time 2016 Chin. Phys. B 25 050701

[1]	Porstendörfer J, Butterweck G and Reineking A 1991 Atmospheric Environment 25A 709
[2]	Jacobi W and Andre K 1963 J. Geophys. Res. 68 3799
[3]	UNSCEAR 1982 United Nations Publications (New York)
[4]	UNSCEAR1993 United Nations Publications (New York)
[5]	Marenco A and Fontan J 1974 Tellus 26 386
[6]	Porstendörfer J, Reineking A, Butterweck G and El-Hussein A 1990 Aerosols: Science, Industry, Health and Environment II pp. 1217
[7]	ICRP 1994 Annals of ICRP Publication 66
[8]	ICRP 1987 Annals of ICRP Publication 50 17
[9]	Porstendörfer J, Butterweck G and Reineking A 1994 Health Physics 67 283
[10]	El-Hussein A, Mohamed A, Abd El-Hady M, Ahmed A A, Ali A E and Barakat A 2001 Atmospheric Environment 35 4305
[11]	Sesana L, Caprioli E and Marcazzan G M 2003 Environmental Radioactivity 65 147
[12]	Baciu A C 2005 Environmental Radioactivity 83 171
[13]	Singh K, Singh M, Singh S, Sahota H S and Papp Z 2005 Radiation Measurements 39 213
[14]	Omori Y, Tohbo I, Nagahama H, Ishikawa Y, Takahashi M, Sato H and Sekine T 2009 Radiation Measurements 44 1045
[15]	Podstawczynska A, Pawlak W, Kozak K and Mazur J 2010 Nukleonika 55 543
[16]	Butterweck G, Reineking A, Kesten J and Porstendörfer J 1994 Atmospheric Environment 28 1963
[17]	Poet S E, Moore H E and Martell E A 1972 Geophys. Res. 77 6515
[18]	Rangarajan C 1992 Environmental Radioactivity 15 193
[19]	Papastefanou C and Bondietti E A 1991 Aerosol Science 22 927
[20]	El-Hussein A, Mohamed A and Ahmed A A 1998 Radiation Protection Dosimetry 78 139
[21]	Marley N A, Gaffiney J S, Drayton P J, Cunningham M M, Orlandini K A and Paode R 2000 Aerosol Science and Technology 32 569
[22]	Baskaran M and Shaw G E 2001 Aerosol Science 32 443
[23]	McNeary D and Baskaran M 2007 Geophysics Research 112 4028
[24]	Papastefanou C 2009 Aerosol Air Quality Research 9 385
[25]	Baskaran M 2011 Environmental Radioactivity 102 500
[26]	Su C C and Hu C A 2002 Geophys. Res. Lett. 29 1070
[27]	Gäggeler H W, Jost D T, Baltensperger U and Schwikowski M 1995 Atmospheric Environment 29 607
[28]	Ahmed A A, Mohamed A, Ali A E, Barakat A, Abd El-Hady M and El-Hussein A 2004 Environmental Radioactivity 77 275
[29]	Vecchi R, Marcazzan G and Valli G 2005 Environmental Radioactivity 82 251
[30]	Porstendörfer J, Wicke A and Schraub A 1980 Natural Radiation and Environment III 2 1293
[31]	Wicke A and Porstendörfer J 1983 Proceedings of the International Meeting EPA 520/583/021 (Washington, D.C.)
[32]	Ruffle M P 1967 Nuclear Instruments and Methods 52 354
[33]	NCRP 1987 National Council on Radiation Protection and Measurements, Bethesda (NCRP Report No. 94)
[34]	UNSCEAR 2000 United Nations Scientific Committee on the Effects of Ionizing Radiation (New York)
[35]	Gogolak C V and Beck H L 1980 Natural Radiation Environment II 259 Department of Energy, (Washington, DC)
[36]	Nagaraja K, Prasad B S N, Madhava M S, Chandrashekara M S, Paramesh L, Sannappa J, Pawar S D, Murugavel P and Kamra A K 2003 Radiation Measurements 36 413
[37]	Chan S W, Lee C W and Tsui K C 2010 Environmental Radioactivity 101 494
[38]	Zhang L and Guo Q 2011 Radiological Protection 31 129

[1]	Synchronous detection of multiple optical characteristics of atmospheric aerosol by coupled photoacoustic cavity Hua-Wei Jin(靳华伟), Ren-Zhi Hu(胡仁志), Pin-Hua Xie(谢品华), and Ping Luo(罗平). Chin. Phys. B, 2022, 31(6): 060703.
[2]	Wide dynamic detection range of methane gas based on enhanced cavity absorption spectroscopy Yu Wang(汪玉), Bo-Kun Ding(丁伯坤), Kun-Yang Wang(王坤阳), Jiao-Xu Mei(梅教旭), Ze-Lin Han(韩泽林), Tu Tan(谈图), and Xiao-Ming Gao(高晓明). Chin. Phys. B, 2022, 31(4): 040705.
[3]	Design of NO₂ photoacoustic sensor with high reflective mirror based on low power blue diode laser Hua-Wei Jin(靳华伟), Pin-Hua Xie(谢品华), Ren-Zhi Hu(胡仁志), Chong-Chong Huang(黄崇崇), Chuan Lin(林川), Feng-Yang Wang(王凤阳). Chin. Phys. B, 2020, 29(6): 060701.
[4]	Atmospheric N₂O gas detection based on an inter-band cascade laser around 3.939 μm Chun-Yan Sun(孙春艳), Yuan Cao(曹渊), Jia-Jin Chen(陈家金), Jing-Jing Wang(王静静), Gang Cheng(程刚), Gui-Shi Wang(王贵师), Xiao-Ming Gao(高晓明). Chin. Phys. B, 2020, 29(1): 010704.
[5]	Novel infrared differential optical absorption spectroscopy remote sensing system to measure carbon dioxide emission Ru-Wen Wang(王汝雯), Pin-Hua Xie(谢品华), Jin Xu(徐晋), Ang Li(李昂). Chin. Phys. B, 2019, 28(1): 013301.
[6]	Absolute density measurement of nitrogen dioxide with cavity-enhanced laser-induced fluorescence Zheng-Hai Yang(杨正海), Yong-Cheng Yang(杨永成), Lian-Zhong Deng(邓联忠), Jian-Ping Yin(印建平). Chin. Phys. B, 2018, 27(10): 100601.
[7]	Measurements of atmospheric NO₃ radicals in Hefei using LED-based long path differential optical absorption spectroscopy Xue Lu(卢雪), Min Qin(秦敏), Pin-Hua Xie(谢品华), Jun Duan(段俊), Wu Fang(方武), Liu-Yi Ling(凌六一), Lan-Lan Shen(沈兰兰), Jian-Guo Liu(刘建国), Wen-Qing Liu(刘文清). Chin. Phys. B, 2016, 25(2): 024210.
[8]	Theoretical analysis of stack gas emission velocity measurement by optical scintillation Yang Yang (杨阳), Dong Feng-Zhong (董凤忠), Ni Zhi-Bo (倪志波), Pang Tao (庞涛), Zeng Zong-Yong (曾宗泳), Wu Bian (吴边), Zhang Zhi-Rong (张志荣). Chin. Phys. B, 2014, 23(4): 040703.
[9]	Cross-interference correction and simultaneous multi-gas analysis based on infrared absorption Sun You-Wen (孙友文), Zeng Yi (曾议), Liu Wen-Qing (刘文清), Xie Pin-Hua (谢品华), Chan Ka-Lok (陈嘉乐), Li Xian-Xin (李先欣), Wang Shi-Mei (汪世美), Huang Shu-Hua (黄书华). Chin. Phys. B, 2012, 21(9): 090701.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

Daily variation of radon gas and its short-lived progeny concentration near ground level and estimation of aerosol residence time

Cite this article:

Online attention