Abstract
Since the existence of the world, human beings have been exposed to natural radiation. Determining the natural radiation level and the radiological parameters is very important in terms of determining the amount of radiation people will be exposed to. Since the population of Istanbul is very high, the number of people that will be affected by the radiation level there is high. In this study, it was aimed to determine the natural radiation level and radiological parameters in Cekmeköy district of Istanbul. For this, natural radionuclides were measured with gamma spectroscopy system based on NaI(Tl) detector for 17 soil samples collected from Cekmeköy-Istanbul. As a result of this study, the mean activity concentrations of 40 K, 226Ra, and 232Th obtained as a result of the measurements were found to be 449 ± 9, 29 ± 1, and 28 ± 1 Bqkg−1, respectively. Mean absorbed dose rate (DR) and excess lifetime cancer risk (ELCR) were calculated as 49 nGyh−1 and 0.21 × 10−3, respectively. Basic statistics were performed to determine the relationship between the activity concentrations of radionuclides and radiological parameters. In conclusion, mean natural radioactivity and radiological parameter levels are calculated lower than the world average.
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Introduction
Human are exposed to two kinds of radiation, natural and artificial, in their daily lives (Gunay et al. 2018; Çelen et al. 2019). A large part of the total radiation exposure of living beings is due to natural source radiation. Natural background radiation in the soil comes from 40 K, 226Ra, and 232Th is the source of about 80% of the total radiation dose a person experiences in a year. Because each region in the world has a unique geological and geographical structure (Külahçı et al. 2020; Kulalı 2020), the activity concentrations of natural radionuclides in the soil may vary from region to region (Turgay 2019, Akkurt etal. 2015).
The concentration and distribution of radionuclides are the main subject of many scientific studies in the evaluation and monitoring of environmental radioactivity. The concentration of radionuclides in the soil is important for finding the source of natural radioactivity, determining environmental effects and assessing radiation risks (Tekin et al. 2020; Çelen & Evcin 2020; El-Agawany F.I et al. 2021, Çelen 2021). For this reason, many researchers in different parts of the world have studied natural radiation activity concentrations of different types of materials, especially terrestrial origin (Malidarre et al. 2020, Kayıran. 2021, Malidarre and Akkurt, 2021, Baykal et al 2021). In these studies, various radiation hazard indexes were calculated using the conversion factors given in UNSCEAR reports and natural radionuclide concentrations to determine health risks (Akkurt & Tekin 2020; Rammah et al. 2020; Tekin et al. 2018).
The main purpose of this study is to determine the natural radioactivity concentrations in some soil samples in Çekmeköy-İstanbul. In addition, various radiological parameters were calculated using natural radioactivity results. These radiological parameters are radium equivalent activity (Raeq), absorbed dose rate (D), annual effective dose (AED), annual gonadal dose equivalent (AGDE), excess lifetime cancer (ELCR), danger indices (Hex and Hin), and gamma representative level index (Iγ). In addition, statistical analyses (basic statistics, histograms, and Pearson correlation analyses) were performed to determine the relationships between the activity concentrations of radionuclides and radiological parameters. As a result of these calculations, the radiation dose level to which the people in the study area will be exposed, and the risk of potential cancer was determined.
Material and method
Soil sample collection and preparation
Istanbul is one of the most populous cities of both Europe and Turkey with a population of approximately 16 million. It is also the center of both tourism and trade in Turkey. People in Istanbul are more likely to be affected by radiation because of the high population. Therefore, Istanbul has been determined as the study area. Natural radiation measurements were made in some districts of Istanbul. A comprehensive natural radiation study has not been carried out in the Cekmeköy district of Istanbul. Determining the natural radiation level and radiological parameters in this district is very important in terms of determining the level of radiation that people living in this district will be exposed to. For these reasons, it has been chosen as the Cekmeköy district of Istanbul as the study area.
Within the scope of this study, soil samples were collected from 17 different locations in Istanbul-Cekmeköy region (Fig. 1 and Fig. 2). Each of the soil samples collected weighs approximately 500 g. Soil samples were collected with a core tool up to 10 cm deep. All soil samples were dried in an oven at about 110 °C for 24 h to ensure complete removal of moisture. Soil samples were sieved with a 1-mm mesh sieve to homogenize the stones, pebbles, and other macro impurities after grinding. Homogenized soil samples were placed in a standard 500 ml airtight PVC plastic container. After the lids were tightly closed, the lids were tightly sealed with vinyl tape to prevent possible escape of the radon gases. Finally, prior to measurement, soil samples were stored for a period of 4 weeks to ensure radioactive secular equilibrium between 238U (226Ra) and 232Th (228Ra) and their progeny.
Gamma spectrometric analysis
The activity concentrations of natural radionuclides in soil samples prepared for measurement were determined using gamma ray spectrometry. This spectrometer system contains thallium-activated sodium iodide (NaI(Tl)) scintillation crystal connected to photomultiplier tubes. When designing the geometry of the measuring system, the detector is placed in the lead block to reduce the effects of background radiation on the measurements.
Energy calibration and detection efficiency of the system are required before the measurements of natural radioactivity. Energy calibration was done using radioactive sources of 137Cs (662 keV) and 60Co (1173 and 1332 keV), whose γ-energies are known. By recording counts from different sources, the energy of incoming radiation over a wide energy range was distinguished. The equation of the curve passing through the points determined by using the energy of the incident peak and the channel number where that peak is detected was obtained by the least squares method.
The detector efficiency calibrations were performed with a certified standard gel source with a similar density to the measured samples (Kuluozturk et al. 2020). The obtained efficiency calibration curve is displayed in Fig. 3.
As can be seen from Fig. 3, the efficiency values are consistent since the R2 value is 0.937.
In the analysis of the spectra obtained as a result of the measurements, the areas of the spectra were calculated using the computer software MAESTRO32. The amount of natural radioactivity of 40 K, 226Ra, and 232Th natural elements was calculated using photopics in 1461, 1760, and 2610 keV gamma ray energies, respectively, in the natural gamma ray spectrum (Akkurt et al. 2014).
The activities of 40 K, 226Ra, and 232Th natural radionuclides were calculated using the following equation with the help of spectrum fields (Beretka and Mathew 1985).
where NS is the net photopic area for the sample, NB is the background photopic area, Eγ is the gamma ray detection efficiency, Pγ is the gamma ray emission probability, t is the measurement time, and MS (kg) is the dry mass of the soil samples.
Results and discussion
40 K, 226Ra, and 232Th activity concentrations
The results of this study are shown in Table 1. The range and average values (in brackets) of the activities for 40 K, 226Ra, and 232Th are 294–612 (449 ± 9), 19–41 (29 ± 1), and 18–39 (28 ± 1) Bqkg−1, respectively. In the results obtained, 40 K activity always contributes greatly to the specific activity compared to 232Th and 226Ra in all soil samples studied.
In UNSCEAR 2000 reports, the world’s mean values of activity concentrations of primordial radionuclides 40 K, 226Ra, and 232Th are 400, 35, and 30 Bqkg−1, respectively (UNSCEAR, 2000). The mean concentrations of 226Ra and 232Th were lower than the world’s average values in all soil samples, while the mean values of 40 K were higher than the world’s average values. The measured activity concentrations for 40 K, 226Ra, and 232Th are illustrated in Fig. 4.
In many countries, studies have been carried out to measure the level of natural radioactivity in the soil. In Table 2, the activity concentrations of the 40 K, 226Ra, and 232Th radionuclides in soil samples obtained in this study are compared with studies carried out in other countries and world mean.
Absorbed gamma dose rate (DR)
Dose rates absorbed in the air 1 m above the location caused by external terrestrial gamma radiation due to the distribution of 40 K, 226Ra, and 232Th natural radioactive elements were calculated. To calculate the absorbed gamma dose rate (DR), dose conversion factors in nGyh−1, which are specified in UNSCEAR2000 reports, are used. These dose conversion factors are 0.0417, 0.462, and 0.604 nGyh−1 for 40 K, 226Ra, and 232Th natural radioactive elements, respectively (UNSCEAR 2000).
where CK, CTh, and CRa are the activity concentrations of 40 K, 226Ra, and 232Th, respectively. The calculated DR results for soil samples have been displayed in Fig. 5. It was observed that DR in soil samples with natural radionuclide measurements ranged from 37 (C-15) to 62 (C-12) nGyh−1 with an average value of 49 nGyh−1. The world mean value for DR is 59 nGyh−1 (UNSCEAR 2000). It can be seen from Fig. 5 that the calculated average DR value in this study area is lower than the world mean.
Annual effective dose (AED)
It is possible to estimate the annual effective dose (AED) using DR calculated above and the outer occupancy factor. The conversion coefficient for DR in the UNSCEAR2000 reports is given as 0.7 SvGy−1. In addition, the external occupancy factor was taken as 0.2, assuming that adults spend approximately 20% of their time outside. Therefore, AED (mSvy−1) was computed by the formula (UNSCEAR 2000).
AED results for soil samples have been displayed in Fig. 6. The range of AED in the studied area is 0.046 (C-15)–0.075 (C-12) mSvy−1, respectively, with the mean of 0.060 mSvy−1. From Fig. 6, it is clear that the mean value of AED is lower than the recommended safety limit of 0.46 mSvy−1(UNSCEAR 2000).
Annual gonadal dose equivalent (AGDE)
Annual gonadal dose equivalent (AGDE) is used to determine the genetic effect of gamma radiation from 40 K, 226Ra, and 232Th natural radionuclides on sensitive organs such as gonads, bone marrow, and bone surface cells. AGDE was calculated using the following equation according to the activity concentration values of the mentioned natural radionuclides (Mamont-Ciesla et al., 1982).
AGDE results in soil samples have been displayed in Fig. 7. The lowest calculated AGDE value is 0.266 mSvh−1 in the sample of C-15 and the highest AGDE value is 0.437 mSvh−1 in the sample of C-12 with the average value of 0.348 mSvy−1.
Excess lifetime cancer risk (ELCR)
In case of exposure to radiation dose for a long time, stochastic effects such as cancer occur. Therefore, a person’s risk of developing cancer is assessed by calculating the risk of over life cancer (ELCR), which varies in direct proportion to the radiation dose. ELCR risk factor can be calculated using the equation below (Günay 2018).
where AED is an annual effective dose equivalent, DL is the average lifetime assumed to be 70 years for an adult person, and RF is a fatal cancer risk factor of 0.05 per Sievert for publicly available stochastic effects in ICRP (1990) reports (ICRP 1990, 1992). From Fig. 8, the lowest calculated ELCR value is 0.160 × 10−3 in the sample of C-15, and the highest ELCR value is 0.264 × 10−3 in the sample of C-12 with an average of 0.210 × 10−3. The average value of ELCR is lower than the world mean value of 0.29 × 10−3 (UNSCEAR 2000).
Radium equivalent activity (Raeq)
Radium equivalent activity (Raeq) index has been defined for the evaluation of radiation hazards associated with these elements of substances containing 40 K, 226Ra, and 232Th natural radioactive elements. This index can be calculated using the relation below (UNSCEAR 2000; Aközcan et al. 2021)
Raeq results for soil samples have been displayed in Fig. 9. Raeq in soil samples ranges from 78.49 (C-15) to 129.01 Bqkg−1 (C-12) with a mean value of 103.59 Bqkg−1 which is less than the recommended maximum value of 370 Bqkg−1.
External and internal hazard index (Hex, Hin)
Health effects of environmental materials such as stone, soil containing 40 K, 226Ra, and 232Th natural radionuclides on health are evaluated with a parameter called external hazard index (Hex). In addition to the external hazard index, radon and short-lived products of environmental materials, which arise due to the indoor use, are also dangerous for health. Internal exposure to radon and its progeny are assessed by the internal hazard index (Hin). These two parameters should not exceed the unit limit in terms of radiation hazard. The external hazard index (Hex) and the internal hazard index (Hin) were quantified from the equations (Günay & Eke 2019).
The Hex and Hin hazard indices results for soil samples have been displayed in Fig. 10. The Hex values ranged from 0.212 (C-15) to 0.348 (C-15) with an average value of 0.280. The Hin values ranged from 0.2563 (C-15) to 0.444 (C-15) with an average value of 0.359. Also it was found that all the values of Hex and Hin are well below the recommended safety limit of ≤ 1 (UNSCEAR 2000).
Gamma representative level index (Iγ)
A representative level index (Iγ) has been defined to determine the level of danger associated with the annual dose rate of excessive external gamma radiation from natural gamma emitters in environmental materials. Depending on the activity concentrations of natural radionuclides, the level of gamma radiation hazard of soil samples was evaluated with the radiation hazard index Iγ and calculated using the following equation (Alam et al. 1999).
Iγ results for soil samples have been displayed in Fig. 10. The calculated values of Iγ vary from 0.591 (C-15) to 0.969 (C-12) with mean value of 0.772. To keep the radiation hazard at harmless values, Iγ must be less than unity. The mean (Iγ) value in the study area is below than the world mean value < 1 (UNSCEAR 2000).
Statistical analysis
In data sets with more than one random variable obtained as a result of measurements or calculations, basic statistical methods are used to analyze the relationship and behavior between variables. In addition, basic statistical analysis helps in organizing and simplifying the data used to evaluate relationships between samples and variables. In this study, SPSS.22.0 was used for basic statistical analysis of the behavior of samples and variables. Basic statistics, histograms and Pearson correlation analyses were performed for the statistical analysis of the results obtained in the study.
Table 3 shows the basic statistics of natural radionuclides in Cekmeköy soil samples such as minimum, maximum, average, standard deviation, variance, skewness, and kurtosis. In this study, the standard deviations of activity concentrations of 40 K, 226Ra, and 232Th natural radionuclides measured in soil samples are smaller than the average values. This indicates that the activity concentration of potassium, uranium, and thorium samples is high homogeneity (Chandrasekaran et al., 2014).
Skewness is defined as the degree of distortion of the symmetricity of the normal distribution curve. The distribution curve is called positive skewed or right skewed if tailed to the right, negative skewed or skewed to the left. In this study, the skewness values of natural radionuclide activity concentrations define the degree of asymmetry around the mean of a distribution. The activity concentrations of the 40 K, 226Ra, and 232Th radionuclides have a positive skewness, indicating that their distribution is asymmetric (Ravisankar et al., 2015). The frequency distribution of 40 K, 226Ra, and 232Th is shown in Fig. 11. Kurtosis is defined as the degree of sharpness or kurtosis (extent) of the normal distribution curve. If the top of the curve is pointed, the distribution is leptokurtic, and it has a high kurtosis coefficient. If the top of the distribution curve is flat, the distribution is plastic, and the flatness coefficient is low (Gupta 2001). The kurtosis value of 40 K, 226Ra, and 232Th activity concentrations is negative, indicating that the curve peaked less than the normal curve.
The strength of the linear relationship between the two variables is defined by the Pearson correlation coefficient. Pearson correlation analysis was applied to determine the relationship between the activity concentrations of 40 K, 226Ra, and 232Th natural radionuclides and their radiological parameters. Correlation coefficients obtained as a result of the analyses are presented in Table 4. The relationship between the activity concentrations of 226Ra and 232Th natural radionuclides and all radiological parameters showed a very high correlation coefficient, but showed that the correlation coefficient between 40 K activity concentration and radiological parameters were low. This analysis showed that the radiological parameters varied depending on the activity concentrations of 226Ra and 232Th natural radionuclides. 40 K activity concentration showed that it is not responsible for radiological parameters.
Conclusion
Activity concentrations of natural radionuclides 40 K, 226Ra, and 232Th were measured in soil samples collected from Çekmeköy-Istanbul using gamma ray spectroscopy technique with NaI (Tl) detector. As a result of this study, the mean activity concentrations of 40 K, 226Ra, and 232Th were found to be 449.12 ± 8.98 Bqkg−1, 29.21 ± 0.58, and 27.83 ± 0.55 Bqkg−1, respectively. Mean absorbed dose rate (DR), annual effective dose (AED), annual gonadal dose equivalent (AGDE), excess lifetime cancer risk (ELCR), and radium equivalent activity (Raeq) were calculated as 49.03 nGyh−1, 0.060 mSvy−1, 0.348 mSvy−1, 0.21 × 10−3, and 103.59 Bqkg−1, respectively. It was concluded that experimentally found average activity concentrations results and theoretically calculated radiological damage parameters were below the recommended safety limit values. Basic statistical analysis showed that the natural radioactivity variation in soil samples in the study area was dependent on thorium and uranium concentration. The data produced in this study will provide basic data for natural radioactivity radiological parameters in the studied area and will be useful for the application of radiation protection standards for people, animals, and the environment living in the region.
References
Ahmed AI, Akrawy DT (2005) Measurement of natural radioactivity in soil samples from bekhma, Kurdistan region, Iraq. Int. J. Recent Res. Rev. VIII (4).
Aközcan S, Külahcı F, Günay O, Özden S (2021) Radiological risk from activity concentrations of natural radionuclides: cumulative hazard index. J Radioanal Nucl Chem 327(1):105–122. https://doi.org/10.1007/s10967-020-07474-1
Akkurt I, Tekin HO (2020) Radiological parameters of bismuth oxide glasses using the Phy-X/PSD software. Emerging Materials Research 9(3):1020–1027. https://doi.org/10.1680/jemmr.20.00209
Akkurt I, Gunoglu K, Arda SS (2014) Detection efficiency of NaI (Tl) detector in 511–1332 keV energy range. Science and Technology of Nuclear Installations.
AKKURT I., N. Ayten UYANIK, Kadir GÜNOĞLU (2015).“ International Journal of Computational and Experimental Science and Engineering 1–1, 1–11 https://doi.org/10.22399/ijcesen.194376
Ahmed AI, Akrawy DT (2005) Measurement of natural radioactivity in soil samples from bekhma, Kurdistan region, Iraq. International Journal of Recent Research and Review, 8(4).
Al-Masri MS et al (2006) External gamma-radiation dose to Syrian population based on the measurement of gamma-emitters in soils. J Radioanaly Nucl Chem 267(2):337–343
Asgharizadeh F, Ghannadi M, Samani AB, Meftahi M, Shalibayk M, Sahafipour SA, Gooya ES (2013) Natural radioactivity in surface soil samples from dwelling areas in Tehran city. Iran Radiat Protect Dosim 156:376–382
Akhtar N, Tufail M, Ashraf M, Mohsi IM (2005) Measurement of environmental radioactivity for the estimation of radiation exposure from saline soil of Lahore. Pakistan Radiat Meas 39:11–14
Alam MN, Chowdhury MI et al (1999) The 226Ra, 232Th and 40K activities in beach sand minerals and beach soils of Cox’s Bazar. Bangladesh Journal of Environmental Radioactivity 46(2):243–250
Bajoga AD, Alazemi N, Shams H, Regan PH, Bradley DA (2017) Evaluation of naturally occurring radioactivity across the state of Kuwait using high-resolution gamma-ray spectrometry. Radiat Phys Chem 137:203–209
Baykal, Ş. D , Tekin, H , Çakırlı Mutlu, R. (2021). International Journal of Computational and Experimental Science and Engineering , 7 -2 , 99 (2021) 108 . https://doi.org/10.22399/ijcesen.960151
Beretka J, Mathew PJ (1985) Natural radioactivity of Australian building materials, industrial wastes and by-products. Health Phys 48:87–95
Chandrasekaran A, Ravisankar R, Senthilkumar G, Thillaivelavan K, Dhinakaran B, Vijayagopal P et al (2014) Spatial distribution and lifetime cancer risk due to gamma radioactivity in Yelagiri Hills, Tamilnadu, India. Egyptian Journal of Basic and Applied Sciences 1(1):38–48
Celik IC, Kosal M (2019) Assessment of environmental radioactivity and health hazard in soil, water, and stone samples in Siverek Town of Sanliurfa Province in Southeastern Turkey. Procedia Comput. Sci 158:125–134
Çelen YY, Evcin A (2020) Synthesis and characterizations of magnetite–borogypsum for radiation shielding. Emerging Materials Research 9(3):770–775. https://doi.org/10.1680/jemmr.20.00098
Çelen YY (2021) . Emerging Materials Research 10–2. (2021) https://doi.org/10.1680/jemmr.21.00043
Çelen YY, Evcin A, Akkurt I, Bezir NÇ, Günoğlu K, Kutu N (2019) Evaluation of boron waste and barite against radiation. Int J Environ Sci Technol 16(9):5267–5274. https://doi.org/10.1007/s13762-019-02333-3
El-Agawany F.I., Karem Abdel-Azeem Mahmoud, Hakan Akyildirim, El-Sayed Yousef, Huseyin Ozan Tekin, Yasser Saad Rammah. (2021). Emerging Materials Research 10–2, 227 https://doi.org/10.1680/jemmr.20.00297
Günay O (2018) Assessment of lifetime cancer risk from natural radioactivity levels in Kadikoy and Uskudar District of Istanbul. Arab J Geosci 11(24):782
Günay O, Saç MM, Içhedef M, Taşköprü C (2018) Natural radioactivity analysis of soil samples from Ganos fault (GF). Int. J. Environ. Sci. Technol 16:1735–1472
Günay O, Eke C (2019) Determination of terrestrial radiation level and radiological parameters of soil samples from Sariyer-Istanbul in Turkey. Arab J Geosci 12(20):1–10. https://doi.org/10.1007/s12517-019-4830-1
Gupta SP (2001) Statistical Methods. Sultan Chand & Sons Publications, New Delhi
Harb S, El-Kamel AEH, Abbady AEB, Saleh II, El-Mageed AIA (2012) Specific activities of natural rocks and soils at quaternary intraplate volcanism north of Sana’a, Yemen. J. Med. Phys. Assoc. Med. Phys. India 37(1):54
Huy NQ, Hien PD, Luyen TV et al (2012) Natural radioactivity and external dose assessment of surface soils in Vietnam. Radiat Prot Dosim 151(3):522–531
ICRP (1990) Recommendations of the International Commission on Radiological Protection, ICRP Publication 60. Pergamon Press Annals of the ICRP, Oxford, p 1990
ICRP (1992) International Commission on Radiological Protection) Protection against radon-222 at home and at work (ICRP Publication 65) Annals of the ICRP, 23(2. Pergamon Press, Oxford
Kayıran HF (2021). Emerging Materials Research. https://doi.org/10.1680/jemmr.21.00052
Kulali F (2020) Simulation studies on the radiological parameters of marble concrete. Emerging Materials Research 9(4):1341–1347. https://doi.org/10.1680/jemmr.20.00307
Fatih KM, Çelik ŞK, Doğru M (2020) Assessment of gamma radiation levels of beach sands in Bitlis region of Lake Van. Arab J Geosci 13:608. https://doi.org/10.1007/s12517-020-05600-7
Külahcı F, Aközcan S, Günay O (2020) Monte Carlo simulations and forecasting of Radium-226, Thorium-232, and Potassium-40 radioactivity concentrations. J. Radioanal. Nucl. Chem 324:55–70
Malidarre RB, Kulali F, Inal A, Oz A (2020) Monte Carlo simulation of a waste soda–lime–silica glass system containing Sb2O3 for gamma-ray shielding. Emerging Materials Research 9(4):1334–1340. https://doi.org/10.1680/jemmr.20.00202
Malidarre BR, Akkurt I (2021) J Mater Sci: Mater Electron 32:11666. https://doi.org/10.1007/s10854-021-05776-y
Mamont-Ciesla KBMAG, Gwiazdowski B, Biernacka M, Zak A (1982). Radioactivity of building materials in Poland. In Natural radiation environment.
Ravisankar R, Chandramohan J, Chandrasekaran A, Jebakumar JPP, Vijayalakshmi I, Vijayagopal P, Venkatraman B (2015) Assessments of radioactivity concentration of natural radionuclides and radiological hazard indices in sediment samples from the East coast of Tamilnadu, India with statistical approach. Mar Pollut Bull 97(1–2):419–430
Rammah YS, Kumar A, Mahmoud KAA, El-Mallawany R, El-Agawany FI, Suso G, Tekin HO (2020) SnO-reinforced silicate glasses and utilization in gamma-radiation-shielding applications. Emerging Materials Research 9(3):1000–1008. https://doi.org/10.1680/jemmr.20.00150
Reddy U, Ningappa C, Sannappa J (2017) Natural radioactivity level in soils around Kolar Gold Fields, Kolar district, Karnataka. India J Radioanal Nucl Chem 314:2037–2045
Tekin HO, Issa SAM, Mahmoud KAA et al (2020) Nuclear radiation shielding competences of barium-reinforced borosilicate glasses. Emerging Materials Research 9(4):1131–1144. https://doi.org/10.1680/jemmr.20.00185
Tekin HO, Baris CAVLI, Elif Ebru ALTUNSOY, Tugba MANICI, Ceren OZTURK, Hakki Muammer KARAKAS (2018). International Journal of Computational and Experimental Science and Engineering 4–2,37. https://doi.org/10.22399/ijcesen.408231
Turgay ME (2019) Cancer risk determination for IDA villages by using annual gamma doses in air, around Edremit&Ayvacık districts; Balıkesir & Çanakkale. TURKEY Avrupa Bilim Ve Teknoloji Dergisi 15:433–439
UNSCEAR (2000) Sources and effects of ionizing radiation, Vol. 1. United Nations Scientific Committee on the Effects of Atomic Radiation. Report of the General Assembly with Scientific Annexes. United Nations, New York;
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Akkurt, İ., Gunoglu, K., Gunay, O. et al. Natural radioactivity and radiological damage parameters for soil samples from Cekmekoy-İstanbul. Arab J Geosci 15, 53 (2022). https://doi.org/10.1007/s12517-021-09351-x
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DOI: https://doi.org/10.1007/s12517-021-09351-x