Skip to main content

REVIEW

Oncol Rev., 05 September 2022

A Review of Studies on the Seasonal Variation of Indoor Radon-222 Concentration

Guadie Degu Belete
&#x;Guadie Degu Belete*Aragaw Msganaw ShiferawAragaw Msganaw Shiferaw
  • Physics Department, College of Natural and Computational Sciences, Assosa University, Assosa, Ethiopia

Due to their electrostatic nature, radon decay products can attach to solid particles and aerosols in the air. Inhalation and ingestion are therefore the two main routes through which people are exposed to radon and its decay products. During the inhalation of these radioactive aerosols, deposition takes place in different regions of the human respiratory tract. The deposited aerosols carrying radon and its progeny undergo a continuous radioactive transformation and expose the lung to ionizing alpha radiation, which can destroy the sensitive cells in the lung, causing a mutation that turns cancerous. Radon which is a colorless, odorless, and tasteless radioactive noble gas is a major health concern and is the second leading cause of lung cancer. To address this, an indoor radon survey was conducted in many countries internationally, with results showing that indoor radon concentration has a seasonal variation. This is due to the fluctuation of environmental parameters and the geological nature of buildings. Its concentration was found to be maximum in the cool (winter) season and a minimum concentration was recorded in the warm (summer) season of the year.

Introduction

Since the existence of life began, living things in the universe, including humans, animals, and plants, have been exposed to natural radiation (1). Our world is full of radioactivity, with over 60 radionuclides found in nature (2). These radionuclides are the source of radioactivity and emit nuclear radiation which has become a part of our daily lives. Radiation is present everywhere and human beings are directly or indirectly exposed to radiation continuously. This radiation comes from different natural and human-made sources. The ionizing radiation originates from soils, water, building materials, air, water, mining areas, and cosmic origins, etc (2). Every day, we ingest or inhale nuclides in the air we breathe, in the food we eat, and in the water we drink. Therefore we have to investigate whether the natural radioactive level of the environment where human beings live is suitable for healthy living.

Human populations can be exposed to manmade and natural radiation sources. The natural radiation surrounding life on earth can either be terrestrial or extraterrestrial (cosmic) in origin. Terrestrial radiation includes the ionizing radiation arising from radionuclides in the earth’s environment, originating from the soil, rocks, construction materials, water, air, and mining areas, and cosmic rays are high energy radiations that enter the earth’s atmosphere from outer space (3). Radioactive elements such as 238U, 232Th, and their decay products, 226Ra, 222Rn, as well as 40K are major sources of radiation of natural origin (4). Ionizing radiations such as α, β, and γ radiations are emitted out from different terrestrial materials from which soil is a major source of natural radioactivity, as the main source for the migration and transfer of radionuclides into the surrounding environment (5). Different studies have been undertaken all over the world to determine the activity concentration of these radioactive elements, which are the main sources of natural radiation in the soil through which human beings experience direct contamination (6). The magnitude of these natural exposures depends on geographical location and some human activities (7).

Human beings can also be exposed to man-made radiation sources in addition to natural radiation sources. Radiation has different applications in various sectors such as medicine, biology, industry, agriculture, and electric power generation. During their application, humans can be exposed to the radiation emitting from different radioactive sources and exposed to different radiation-induced diseases (8). Man-made sources, known as artificial radionuclides, include medical radiation sources (x- rays and radioactive isotopes that are used in medicine for diagnosis and therapy), consumer products: [Such as static eliminators (containing polonium-210), smoke detectors (containing americium-241), cardiac pacemakers (containing plutonium-238), fertilizers (containing isotopes potassium, from uranium and thorium decay series), and tobacco products (containing polonium-210 and lead-210)], as well as atmospheric testing of nuclear weapons (radiations released during the testing of nuclear weapons and nuclear power generation). More than 80% of human exposure comes from natural radioactivity from different sources (9), and the rest is contributed by man-made radiation sources.

Radon (Rn), which is a radioactive decay product of one of the members of the uranium decay series called radium (Ra), is a radioactive, colorless, odorless, and tasteless noble gas, which makes it difficult to detect without special equipment. There are three known radon isotopes; Radon (222Rn) which has a half-life of 3.82 days, Thoron (220Rn) which has a half-life of 55.8 s, and Actinon (219Rn) which has a half-life of 3.98 s 222Rn, 220Rn, and 219Rn are found in the decay chain of the three uranium isotopes of 238U, 236U, and 235U, respectively (9, 10, 11). Uranium can be found in soil, rock, building materials, groundwater, and mining areas (12). Even though soil is the major source of radon, different building materials such as cement, rock, concrete, marble, paints, and gypsum contain uranium and radium (13). Radon is the leading source of ionizing radiation received by humans. It contributes around 55% of the environmental background radiation dose identified as a health hazard for mankind (13, 14). It is found in variable concentrations from location to location depending on the geological nature of that particular place (11).

Radon is radioactive nuclei, which means it is unstable and hence undergoes a continuous radioactive transformation and forms several short-lived radioactive decay products called radon progenies. Polonium (218Po), lead (214Pb), bismuth (214Bi), and polonium (214Po) are successive radon decay products. Under each radioactive transformation alpha radiation, beta radiation, or sometimes gamma radiation is emitted (11). Over 90% of the radiation dose from radon is contributed by the two alpha radiation emit decay products called polonium (218Po) and lead (214Pb) (15). Figure 1 presents radon found from radium and its decay products are unstable and undergo radioactive decay by emitting ionizing alpha and beta particles which can cause great damage to human tissues.

FIGURE 1
www.frontiersin.org

FIGURE 1. Radioactive decay chain of radon.

Indoor Radon and Its Health Effect

The earth’s atmosphere is full of gas with liquid and solid particles. Particles in the air are known as aerosols, which have various sizes, shapes, and chemical compositions. Mostly radius and diameter of aerosols can be used to define their size. Due to their size and differences in shape, they have different settling velocities and diffusion coefficients.

When radon is exhaled into the earth’s environment from different sources such as soil, rock, building materials, groundwater, and mining areas through diffusion and emanation, its daughters become attached to the mono-dispersed and poly-dispersed aerosols due to their electrostatics characteristics (16). In these radioactive decay products, electrons are stripped from the parent atom by its recoil, and decay products are formed as positive ions. These ions can attract liquid and even solid materials from their surroundings, thus forming clusters of atoms or particles in the submicron region ranging from 0.0005 to 10 μm (17). Figure 2 presents the mechanisms of radioactive aerosol formation. Depending on the amount of aerosol concentration of the surrounding environment and humidity of the surrounding environment, around 80% of the radon decay progenies will be attached to the aerosols in the air that we take in.

FIGURE 2
www.frontiersin.org

FIGURE 2. Aerosol formation of radon decay products.

Inhalation and ingestion are the two main routes by which human beings are exposed to radon and its decay products. After the inhalation and ingestion of aerosols carrying radon take place, it releases energetic alpha radiation with some associated gamma radiation that can damage the sensitive cells of the lung and stomach and induce cancer. Radon is a noble gas, it is non-reactive and is exhaled after being breathed in, but its decay products combined with other particles in the air such as dust or aerosols will be deposited on the surface of different regions of the respiratory system. Two of its decay products, Polonium (218Po) and lead (214Pb) are significantly hazardous. The deposited radioactive aerosols continued to undergo a successive radioactive spontaneous transformation. Under each decay, energetic alpha radiation is bombarded with the vital molecules in the lung cells causing a DNA structure break which causes mutations that turn into lung cancer (18).

Based on several investigations in Europe, North America, and China there is a direct relation between indoor radon concentration and inducing lung cancer. In these studies, radon was identified as the second leading cause of lung cancer after cigarettes (9). Different countries and organizations have dedicated activities to reducing radon health risks, as people need to take action when radon concentration exceeds the recommended safe limits. The World Health Organization (WHO) and Environmental Protection Agency (EPA) suggest that homeowners take action when radon levels exceed 100 Bq/m3 and 148 Bq/m3, respectively (11, 15).

Major Factors Affecting Indoor Radon Concentration

Exposure to radon and its progeny is not limited to specific industries, for example, underground miners, and people working in indoor environments are also exposed to radon and its decay products. Uranium is a widely distributed constituent of the earth’s crust, typically in 2–4 parts per million, and in consequence, is found in most materials commonly used by the building industry. In the confined places of buildings and houses that do not allow air exchange radon gas can accumulate, and diffuse from building materials and soils, meaning that the people living and working there can easily inhale radon and its decay products (19) and it can accumulate to a harmful level. Different housing and environmental factors such as the types of construction materials of the building, the soil composition around the house, design of the house, construction, and level of ventilation of the house are major factors that determine the amount of indoor radon (222Rn) concentration (20).

The probability of inducing lung cancer in an occupied room is increased when the indoor radon concentration is high. Hence, different studies have been conducted concerning radon and its decay products. To understand the distribution of radon concentration in dwellings, different indoor radon surveys have been performed in different countries of the world. The results of these surveys indicate that the amount of indoor radon concentration has a strong variation with time. In general, one can study this in terms of two types of variations: daily and seasonal variation. In the diurnal context, the amount of indoor radon concentration is found to be maximum during the night and early morning, while the minimum concentration is recorded during the day (9). To manage the health hazards of radon and its progeny, one needs to study the seasonal variation of indoor radon concentration.

The results of different papers show that the concentration of radon and its decay products in dwellings varies from season to season. Meteorological parameters, geology, building materials, building construction type, and the degree of ventilation in closed environments are among the most important factors affecting radon in indoor air (21). The fluctuation of weather or environmental parameters such as temperature, pressure, humidity, ventilation condition, and wind speed and direction plays a role in the seasonal variation of indoor radon concentration (22).

Variations in the concentration of radon in homes are related to seasonal change. This is because climate change can cause different effects in terms of the environment or indoor air (22). The windows and doors of buildings during the winter months tend to be closed for longer periods of time due to rain, snow, or ice, which results in a lower ventilation rate in the room, and hence the accumulation of indoor radon tends to rise and can build to harmful levels. During the summer months, people open doors and windows, which increases the ventilation of the house (23). Ventilation rate and radon concentration have an inverse relation. Ventilation rate is key to reducing indoor radon concentration (22) as improvements in ventilation systems normally change radon concentration by less than 50 percent (24). Indoor radon concentration in winter therefore tends to be higher as compared to the other seasons of the year.

The structural formation of the building is also another factor in the variation of the concentration. The geology of different building materials such as cement, rock, concrete, marble, paints, and gypsum always contain uranium and radium (25). Buildings are made from rocks of different ages, origins, minerals, and chemical compositions. Heavy construction materials such as concrete and stone generally increase the thermal mass of the building, meaning there is an increase in the internal air temperature, which keeps the building warmer in summer (26). For this purpose, homeowners can apply different ventilation methods such as installing a radon pump system, opening windows, doors, and vents of the house (called natural ventilation), or using house pressurization via a fan. This makes the radon concentration seasonal, as it is low in warm (summer) and higher in cool (winter) seasons (16, 27).

Result and Discussion

Different articles suggest that there is a relationship between the variation of indoor radon concentration and the construction style of a house. Some houses are constructed with a basement and others are constructed without a basement. The basement is an important construction element of a building. Radon concentrations in buildings with and without basements are different (28). Houses with a basement have greatly increased levels of radon concentration compared to those without a basement. Since radon enters homes from the ground, the presence of a basement is expected to be a determinant of high concentrations (29). Soil is most frequently the main source of radon in building air. The soil permeability of the basement is primarily responsible for the migration of radon into basements, which allows the gas to build up to harmful levels. In confined spaces such as the basements of houses and buildings where air exchange is not allowed, radon can accumulate to harmful levels. It is recommended that basements should not be used for residential purposes if the radon concentration is high.

The construction of the house plays a role in the variation of indoor radon concentration. The construction of houses in urban and rural areas is different due to economic, social, and environmental factors, as reflected in the type of buildings in urban and rural areas. In rural areas such as villages and hamlets, most houses are constructed from mud and local stones. These houses tend to have poor ventilation and are constructed with or without windows. The building materials of these houses, namely stone and soil, allow more radon to diffuse into the room due to the porosity of the materials used, which contributes to a high concentration of radon (25). The buildings in some rural areas of thwe world are smaller, older made from mud (30).

Wind speed and direction are other factors that affect the variation of indoor radon concentration as they affect the pressurization of a room and there is quite often a pressure difference between inside air and atmospheric air (28). In addition, the lifestyle or habits of the homeowners, in terms of shutting and opening doors and windows is another factor that influences levels of indoor radon concentration (22).

The age of a house determines the construction features of the house in terms of technologies and materials. Cracks and lack of continuity appear as construction materials age and increase radon inflow (28). Older homes have higher concentrations of radon because they typically have more cracks in flooring and the foundation and thus have a higher risk of contamination (22).

As has been observed from the data of different published papers, radon concentration is not constant with time. Its concentration shows variations day-to-day and season-to-season. To manage its adverse health effects, one needs to detect its seasonal concentration.

Measurement Technique and Methodology

Different instruments can be applied to measure indoor radon concentrations from active and passive detectors. A passive integrated CR-39 alpha tract detector can be used to measure long-term radon-222 concentration.

In terms of methodology, measurement should ideally be performed four times a year, corresponding to the four seasons, to observe seasonal indoor radon concentrations. The detectors should be placed in the most frequently used parts of the house where the room occupants spent most of their time, such as bedrooms, sitting rooms, or kitchens, etc., To observe the effect of the types of building materials used, detectors should ideally be placed in houses made from different building materials with different designs at a height of 1 m from the floor and 0.5 m from the walls of the building (31, 32). Parallel to the measurement process, the house owners should complete a questionnaire to gather information about the building materials used, age and shape or design of the house, etc.

After the exposure time has elapsed, the detector needs to be etched using the NaOH solution, to enlarge the alpha tracks and get ready for optical microscope observation of the appropriate times and temperatures. The etched tracks can then be converted into radon concentrations by using a conversion factor as follows (33).

CRn=Cf×ρTracks46.8×1000T

where CRn is radon concentration in Bq.m−3, Cf is calibration factor, rTracks is track density (number of tracks per cm2), T is the exposure time in hours.

Discussion

To obtain homogeneous and interrelated results as well as to study the effects of climate change on radon concentration, radon concentration measurements were undertaken during different seasons (34). The measurement period was extended for a year and divided into four periods to represent the four seasons: winter (December–February), spring (March–April), summer (June–August), and autumn (September–November); to ensure that it covered all scenarios (35).

Season variation of indoor radon concentrations was measured in buildings with similar designs in Azarqa town, Jordan (23). An indoor radon survey was conducted in 50 dwellings situated in the Sri Ganganagar district of Rajasthan, using a time-integrated passive technique containing LR-115 type II solid state nuclear track detectors exposed for four seasons (29). Similarly, the seasonal variation of indoor radon concentration was conducted in southern Haryana and Western Utter (27).

The minimum, maximum, and average values of radon concentration in the four seasons in those study areas are given in Tables 13. As observed in the three tables, interestingly, radon concentration shows a seasonal variation. The three tables show common results in terms of maximum radon concentration, which was recorded during the winter season, in contrast to the minimum concentration found during the summer season. This is due to the fluctuation of environmental factors and the geological characteristics of the building.

TABLE 1
www.frontiersin.org

TABLE 1. Statistical summary of radon concentration during different seasons inside shops in Alzarqa Town (23).

TABLE 2
www.frontiersin.org

TABLE 2. Annual indoor radon levels in Karanpur village in the Sri Ganganagar district of Rajasthan (29).

TABLE 3
www.frontiersin.org

TABLE 3. Seasonal variation of indoor radon in southern Haryana and Western Utter (27).

The radon concentration in houses with and without a basement was also studied. The presence and absence of the basement affected the variation of radon concentration in buildings. As seen in Table 4, a higher radon concentration was measured in houses with a basement (28).

TABLE 4
www.frontiersin.org

TABLE 4. Radon distribution in houses with and without basements (28).

Conclusion

Radiation is always around us. We are surrounded by natural and manmade radiation sources but long-term radiation exposure can cause adverse health hazards to humans. Radon, which is the sixth radioactive decay products of uranium, contributes almost half of the natural radiation to which human beings are exposed. The International Agency for Research on Cancer, therefore, classified radon as a human carcinogen. Due to its health hazards, different research has been conducted to determine its concentration in a place where human beings live. Indoor radon concentration has a seasonal variation. Its concentration was found to be maximum in the cool (winter) season and a minimum concentration was recorded in the warm (summer) season. The seasonal concentration of indoor radon concentration in homes, offices, schools, hospitals, shops, and industrial buildings needs to be studied further.

Author Contributions

GB—Methodology, Conceptualization, analysis and investigation, Writing - original draft preparation, Supervision. AS—Writing - review and editing, Material preparation.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

References

1. Banari, BS. The Calculation of the Annual Effective Dose Due to Exhalation of Radon Progeny in Iran. J Appl Environ Biol Sci (2015) 5, 609–13.

Google Scholar

2. Obaid, SS, Gaikwad, DK, and Pawar, PP. Determination of Natural Radioactivity and hazard in Some Rock Samples. Bionano Frontier (2015) 8(3):125–7.

Google Scholar

3.United Nations Scientific Committee on the Effects of Atomic Radiation and Annex B. Exposures from Natural Radiation Sources. Cosmic rays (2000) 9:11.

Google Scholar

4. Najam, LA, Younis, SA, and Kithah, FH. Natural Radioactivity in Soil Samples in Nineveh Province and the Associated Radiation Hazards. Int J Phys (2015) 3(3):126–32.

Google Scholar

5. Taqi, AH, Shaker, AM, and Battawy, AA. Natural Radioactivity Assessment in Soil Samples from Kirkuk City of Iraq Using HPGe Detector. Int J Radiat Res (2018) 16(4):455–63.

Google Scholar

6. Thabayneh, K. Natural Radioactivity Levels and Estimation of Radiation Exposure in Environmental Soil Samples from Tulkarem Province–Palestine. Open J Soil Sci (2012) 2:7–16. doi:10.4236/ojss.2012.21002

CrossRef Full Text | Google Scholar

7. Baba, A, Bassari, A, Erees, F, and Cam, S. Natural Radioactivity and Metal Concentrations in Soil Samples Taken along the Izmir-Ankara E-023 Highway. Turkey (2004).

Google Scholar

8. Cengiz, GB, and Öztanriöver, E. Analysis of Natural Radioactivity Levels in Soil Samples and Dose Assessment for Digor District, Kars, Turkey. Caucasian J Sci (2018) 5(1):30–9.

Google Scholar

9. Pantelić, G, Čeliković, I, Živanović, M, Vukanac, I, Nikolić, JK, Cinelli, G, et al. Qualitative Overview of Indoor Radon Surveys in Europe. J Environ Radioactivity (2019) 204:163–74. doi:10.1016/j.jenvrad.2019.04.010

CrossRef Full Text | Google Scholar

10. Senitkova, IJ, and Kraus, M. Seasonal and Floor Variations of Indoor Radon Concentration. IOP Conf Ser Earth Environ Sci (2019) 221(1):012127. doi:10.1088/1755-1315/221/1/012127

CrossRef Full Text | Google Scholar

11. Degu Belete, G, and Alemu Anteneh, Y. General Overview of Radon Studies in Health Hazard Perspectives. J Oncol (2021) 2021:1–7. doi:10.1155/2021/6659795

CrossRef Full Text | Google Scholar

12. Bowie, C, and Bowie, SHU. Radon and Health. Lancet (1991) 337(8738):409–13. doi:10.1016/0140-6736(91)91177-v

PubMed Abstract | CrossRef Full Text | Google Scholar

13. Chalmers, B, Mangiaterra, V, and Porter, R. WHO Principles of Perinatal Care: the Essential Antenatal, Perinatal, and Postpartum Care Course. Birth (2001) 28(3):202–7. doi:10.1046/j.1523-536x.2001.00202.x

PubMed Abstract | CrossRef Full Text | Google Scholar

14. Ravikumar, P, and Somashekar, RK. Estimates of the Dose of Radon and its Progeny Inhaled inside Buildings. Eur J Environ Sci (2013) 3(2):88–95. doi:10.14712/23361964.2015.10

CrossRef Full Text | Google Scholar

15. Gillmore, GK, Phillips, PS, and Denman, AR. The Effects of Geology and the Impact of Seasonal Correction Factors on Indoor Radon Levels: A Case Study Approach. J Environ Radioactivity (2005) 84(3):469–79. doi:10.1016/j.jenvrad.2005.05.004

CrossRef Full Text | Google Scholar

16.P Kulkarni, PA Baron, and K Willeke, editors. Aerosol Measurement: Principles, Techniques, and Applications. John Wiley & Sons (2011).

Google Scholar

17.Constantin Papastefanou. Radioactive Aerosols. Elsevier (2008).

Google Scholar

18. Turtiainen, T. Radon and Radium in Well Water: Measurements and Mitigation of Exposure (2013).

Google Scholar

19. Singh, P, Singh, P, Singh, S, Sahoo, BK, Sapra, BK, and Bajwa, BS. A Study of Indoor Radon, Thoron and Their Progeny Measurement in Tosham Region Haryana, India. J Radiat Res Appl Sci (2015) 8:226–33. doi:10.1016/j.jrras.2015.01.008

CrossRef Full Text | Google Scholar

20. Anastasiou, T, Tsertos, H, Christofides, S, and Christodoulides, G. Indoor Radon (222Rn) Concentration Measurements in Cyprus Using High-Sensitivity Portable Detectors. J Environ Radioactivity (2003) 68(2):159–69. doi:10.1016/s0265-931x(03)00052-3

CrossRef Full Text | Google Scholar

21. Xie, D, Liao, M, and Kearfott, KJ. Influence of Environmental Factors on Indoor Radon Concentration Levels in the Basement and Ground Floor of a Building–A Case Study. Radiat Measurements (2015) 82:52–8. doi:10.1016/j.radmeas.2015.08.008

CrossRef Full Text | Google Scholar

22. Winkler-Heil, R, Hofmann, W, Marsh, J, and Birchall, A. Comparison of Radon Lung Dosimetry Models for the Estimation of Dose Uncertainties. Radiat Prot dosimetry (2007) 127(1-4):27–30. doi:10.1093/rpd/ncm339

PubMed Abstract | CrossRef Full Text | Google Scholar

23. Karpińska, M, Mnich, Z, Kapała, J, and Szpak, A. The Evaluation of Indoor Radon Exposure in Houses. Polish J Environ Stud (2009) 18(6), 1005.

Google Scholar

24. Kant, K, Rashmi, RG, Sonkawade, RG, Sharma, GS, Chauhan, RP, and Chakarvarti, SK. Seasonal Variation of Radon, Thoron and Their Progeny Levels in Dwellings of Haryana and Western Uttar Pradesh. Iranian J Radiat Res (2009) 2:79–84.

Google Scholar

25. Sharma, A, Mahur, AK, Rajendra, P, Sonkawade, RG, and Sharma, AC. Radon Exhalation in Some Building Construction Materials and Effect of Plastering and Paints on the Radon Exhalation Rate Using Fired Bricks. In: Proceedings of the eighteenth national symposium on solid state nuclear track detectors and their applications: abstracts (2013).

Google Scholar

26. Charles, M. UNSCEAR Report 2000: Sources and Effects of Ionizing Radiation. J Radiological Prot (2001) 21(1):83–5. doi:10.1088/0952-4746/21/1/609

PubMed Abstract | CrossRef Full Text | Google Scholar

27. Elzain, AEA. Seasonal Variation of Radon-222 Concentration in Shops and Pharmacies of Alzarqa Town-Jordan. In: The 2011 International AARST Symposium (2011). p. 100.

Google Scholar

28. Neal, F. Geographic Variation of Radon Gas Concentrations in Relationship to Housing Characteristics in Dekalb County, Georgia. Thesis. Atlanta, Georgia: Georgia State University (2016).

Google Scholar

29. Ramola, RC, Kandari, MS, Negi, MS, and Choubey, VM. A Study of Diurnai Variation of Indoor Radon Concentrations. Jpn J Health Phys (2000) 35(2):211–6. doi:10.5453/jhps.35.211

CrossRef Full Text | Google Scholar

30. Muntean, LE, Cosma, C, Cucos, A, Dicu, T, and Moldovan, DV. Assessment of Annual and Seasonal Variation of Indoor Radon Levels in Dwelling Houses from Alba County, Romania. Rom Journ Phys (2014) 59(1-2):163–71.

Google Scholar

31. Giagias, V, Burghele, D, and Cosma, C. Seasonal Variation of Indoor Radon in Dwellings from Athens, Greece. Rom J Phys (2015) 60(9-10):1581–8.

Google Scholar

32. Yousef, AMM, and Zimami, K. Indoor Radon Levels, Influencing Factors and Annual Effective Doses in Dwellings of Al-Kharj City, Saudi Arabia. J Radiat Res Appl Sci (2019) 12(1):460–7. doi:10.1080/16878507.2019.1709727

CrossRef Full Text | Google Scholar

33. Yalim, HA, Gümüş, A, and Ünal, R. Determination of Indoor Radon Concentration and Effective Dose Equivalent at Workplaces of Afyonkarahisar Province. Süleyman Demirel Üniversitesi Fen Edebiyat Fakültesi Fen Dergisi (2018) 13(2):29–35. doi:10.29233/sdufeffd.442298

CrossRef Full Text | Google Scholar

34. Park, JH, Lee, CM, Lee, HY, and Kang, DR. Estimation of Seasonal Correction Factors for Indoor Radon Concentrations in Korea. Int J Environ Res Public Health (2018) 15(10):2251. doi:10.3390/ijerph15102251

PubMed Abstract | CrossRef Full Text | Google Scholar

35. Duggal, V, Rani, A, and Mehra, R. A Study of Seasonal Variations of Radon Levels in Different Types of Dwellings in Sri Ganganagar District, Rajasthan. J Radiat Res Appl Sci (2014) 7(2):201–6. doi:10.1016/j.jrras.2014.02.007

CrossRef Full Text | Google Scholar

Keywords: indoor radon, environmental factors, seasonal variation, lung cancer, building

Citation: Belete GD and Shiferaw AM (2022) A Review of Studies on the Seasonal Variation of Indoor Radon-222 Concentration. Oncol. Rev. 16:10570. doi: 10.3389/or.2022.10570

Received: 13 April 2022; Accepted: 24 June 2022;
Published: 05 September 2022.

Edited by:

Camillo Porta, University of Bari Aldo Moro, Italy

Reviewed by:

Luciano Mutti, Temple University, United States
Vakkas Bozkurt, Niğde Ömer Halisdemir University, Turkey

Copyright © 2022 Belete and Shiferaw. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Guadie Degu Belete, guadedegu1@gmail.com

ORCID: Guadie Degu Belete, https://orcid.org/0000-0001-8361-9578

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.