Variation of indoor radon concentration and ambient dose equivalent rate in different outdoor and indoor environments

The current work deals with indoor radon (222Rn) concentrations and ambient dose-equivalent rate measurements in the bauxite-bearing areas of the Adamawa region in Cameroon before mining from 2022. In total, 90 Electret Ionization Chambers (EIC) (commercially, EPERM) and 175 Radon Track Detectors (commercially, RADTRAK2) were used to measure 222Rn concentrations in dwellings of four localities of the above region. A pocket survey meter (RadEye PRD-ER, Thermo Scientific, Waltham, MA, USA) was used for the ambient dose-equivalent rate measurements. These measurements were followed by calculations of annual doses from inhalation and external exposure. 222Rn concentrations were found to vary between 36 ± 8–687 ± 35 Bq m−3 with a geometric mean (GM) of 175 ± 16 Bq m−3 and 43 ± 12–270 ± 40 Bq m−3 with a geometric mean of 101 ± 21 Bq m−3 by using EPERM and RADTRAK, respectively. According to RADTRAK data, 51% of dwellings have radon concentrations above the reference level of 100 Bq m−3 recommended by the World Health Organization (WHO). The ambient dose equivalent rate ranged between 0.04–0.17 µSv h−1 with the average value of 0.08 µSv h−1. The inhalation dose and annual external effective dose to the public were assessed and found to vary between 0.8–5 mSv with an average value of 2 mSv and 0.3–1.8 mSv with an average value of 0.7 mSv, respectively. Most of the average values in terms of concentration and radiation dose were found to be above the corresponding world averages given by the United Nations Scientific Commission on the Effects of Atomic Radiation (UNSCEAR). Even though the current exposure of members of the public to natural radiation is not critical, the situation could change abruptly when mining starts.

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Exposures from radon, thoron, and thoron progeny in high background radiation area in Takandeang, Mamuju, Indonesia

Nukleonika ◽

10.2478/nuka-2020-0013 ◽

2020 ◽

Vol 65 (2) ◽

pp. 89-94 ◽

Cited By ~ 2

Author(s):

Miki Arian Saputra ◽

Eka Djatnika Nugraha ◽

Tri Purwanti ◽

Rokhmat Arifianto ◽

Roza Indra Laksmana ◽

...

Keyword(s):

Background Radiation ◽

Indoor Radon ◽

Dose Equivalent ◽

High Background ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

High Background Radiation Area ◽

Thoron Progeny ◽

Radiation Area ◽

Ambient Dose

AbstractThe exposure from radon, thoron, and thoron progeny was measured for 45 dwellings in high background radiation area in Takandeang, Indonesia with ambient dose equivalent rate ranging from 0.34 μSv h−1 to 1.90 μSv h−1. The measurement was taken using passive radon and thoron discriminative detector and thoron progeny detector. This measurement was taken from November 2018 to October 2019, and within one month the detector would be replaced with a new detector. The concentrations of radon, thoron, and thoron progeny were calculated as 42–490 Bq m−3, 20–618 Bq m−3, and 4–40 Bq m−3, respectively. The concentrations for outdoor were 49–435 Bq m−3, 23–457 Bq m−3, and 4–37 Bq m−3, respectively, and the annual effective dose was 9.8–28.6 mSv y−1. Based on the result of Spearman’s correlations analysis between the indoor radon and thoron concentrations and between the indoor thoron progeny and thoron concentrations, we suggest that exposure to thoron cannot be predicted from exposure to radon, and the equilibrium equivalent thoron concentration has a large uncertainty when it is estimated from thoron concentration assuming a single thoron equilibrium factor.

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Radiation protection instrumentation. Neutron ambient dose equivalent (rate) meters

10.3403/03168141 ◽

2004 ◽

Keyword(s):

Radiation Protection ◽

Dose Equivalent ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

Ambient Dose

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Radiation protection instrumentation � Installed ambient dose equivalent rate meters, warning and monitoring assemblies for neutrons with energies from thermal to 20 MeV

10.3403/30334767 ◽

2020 ◽

Keyword(s):

Radiation Protection ◽

Dose Equivalent ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

Ambient Dose

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Radiation protection instrumentation - Hand-held instruments for the detection and identification of radionuclides and for the estimation of ambient dose equivalent rate from photon radiation

10.3403/30348912u ◽

2019 ◽

Keyword(s):

Radiation Protection ◽

Photon Radiation ◽

Dose Equivalent ◽

Detection And Identification ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

Ambient Dose

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Study of the screening survey using an ambient dose equivalent rate survey meter in criticality accidents

Progress in Nuclear Science and Technology ◽

10.15669/pnst.6.152 ◽

2019 ◽

Vol 6 (0) ◽

pp. 152-155

Author(s):

Katsuya Hoshi ◽

Norio Tsujimura ◽

Tadayoshi Yoshida ◽

Osamu Kurihara ◽

Eunjoo Kim ◽

...

Keyword(s):

Dose Equivalent ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

Criticality Accidents ◽

Screening Survey ◽

Ambient Dose

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Long-Term Impacts of Weather Conditions on Indoor Radon Concentration Measurements in Switzerland

Atmosphere ◽

10.3390/atmos13010092 ◽

2022 ◽

Vol 13 (1) ◽

pp. 92

Author(s):

Joan Frédéric Rey ◽

Stéphane Goyette ◽

Mauro Gandolla ◽

Martha Palacios ◽

Fabio Barazza ◽

...

Keyword(s):

Radon Concentration ◽

Indoor Radon ◽

Weather Conditions ◽

Indoor Environments ◽

Indoor Radon Concentration ◽

Prone Area ◽

Building Characteristics ◽

Study Sites ◽

Radon Measurements

Radon is a natural and radioactive gas that can accumulate in indoor environments. Indoor radon concentration (IRC) is influenced, among other factors, by meteorology, which is the subject of this paper. Weather parameters impact indoor radon levels and have already been investigated, but rarely in Switzerland. Moreover, there is a strong need for a better understanding of the radon behaviour inside buildings in Switzerland for public health concerns as Switzerland is a radon prone area. Based on long-term, continuous, and hourly radon measurements, radon distributions classified according to different weather event definitions were investigated and then compared at three different study sites in Western Switzerland. Outdoor temperature influences the most indoor radon, and it is globally anti-correlated. Wind influences indoor radon, but it strongly depends on intensity, direction, and building characteristics. Precipitation influences periodically indoor radon levels relatively to their intensity. Atmospheric pressure and relative humidity do not seem to be huge determinants on IRC. Our results are in line with previous findings and provide a vivid example in Western Switzerland. This paper underlines the different influence complexities of radon, and the need to communicate about it within the broader public and with construction professionals, to raise awareness.

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Correction Coefficients for Measuring the Ambient Dose Equivalent Rate of Neutrons

ANRI ◽

10.37414/2075-1338-2021-107-4-32-40 ◽

2021 ◽

Vol 0 (4) ◽

pp. 32-40

Author(s):

Alexander Alexeev ◽

Vladimir Pikalov ◽

Pavel Alexeev

Keyword(s):

Power Plant ◽

Nuclear Power Plant ◽

Nuclear Power ◽

Dose Equivalent ◽

Equivalent Rate ◽

Ambient Dose Equivalent ◽

Ambient Dose

Calculations of the response for the most widely used neutron dosimeters at the Russian nuclear power plant (NPP) have been performed. It is shown that in some cases it is necessary to introduce a correction for the measured value of the ambient dose equivalent rate (AEDR). The experimentally tested values of the correction for measuring AEDR in the containment rooms of NPP with VVER-1200 are given.

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