Layout 6 A ground radiometric study of uranium, thorium and potassium in Isparta, Turkey N. Ayten Uyanik1, Iskender Akkurt2,*, Osman Uyanik3 1 Süleyman Demirel Üniversitesi, Deprem ve Jeoteknik Araştirma Merkezi, Isparta, Turkey 2 Süleyman Demirel Üniversitesi, Fen Edebiyat Fakültesi, Fizik Bölümü, Isparta, Turkey 3 Süleyman Demirel Üniversitesi, Müh-Mim. Fak., Jeofizik Müh. Bölümü, Isparta, Turkey ANNALS OF GEOPHYSICS, 53, 5-6, 2010; doi: 10.4401/ag-4726 ABSTRACT The radioelement concentrations of uranium (238U), thorium (232Th) and potassium (40K), as their radionuclides eU, eTh and K, of Cünür Hill in the city of Isparta (Turkey) and its surroundings were measured using gamma-ray spectrometry with a NaI(Tl) detector. The measurements were performed over an area of 2 km × 8 km around Cünür Hill, which forms part of the Isparta volcanic region that has a trachyandesitic composition, and which included the limestone outcrops east of Cünür. The results are mapped as combined radioelement concentrations. The radioelement concentrations of eU, eTh and K measured for Cünür Hill are high because of its trachyandesitic composition, while those measured in the limestone area were low, as would be expected. 1. Introduction Natural radioactivity has existed since the universe began, and it has survived to date due to the long half-lives of various radioactive element series. These elements are mainly uranium (238U), thorium (232Th), and potassium (40K). Radiometric methods are one of the most powerful and rapid methods to obtain information about the distributions and concentrations of these radionuclides (eU, eTh, K) in any specific areas. Moreover, using these methods, it is also possible to carry out geological and geochemical mapping [Durrance 1986, Aydin et al. 2006, Uyanık and Akkurt 2010]. The region around the city of Isparta (Turkey) is an interesting area, where many different tectonic structures are found. This region is rich in trachyandesitic rock and has large limestone exposures [Görmüşand Özkul 1995, Kanbur et al. 2008]. Several geological studies have been performed on this region [Gutnic et al. 1979, Görmüş and Özkul 1995, Yagmurlu et al. 1997, Koçyigit and Deveci 2007, Plateovet et al. 2008, Kanbur et al. 2008]. However, no complete studies for the regional radiometric data on this area are presently available, although there has been a report of measurements of the natural background radiation [Akkurt 2004]. In the present pilot study, the concentrations of the eU and eThelement series and Kactivities around the Cünür Hill area of Isparta were measured using gamma-ray spectrometry with a NaI(Tl) scintillation detector. Annual effective outdoor doses were also estimated. 2. Materials and methods 2.1. Geological setting The field measurements were performed at 60 locations on Cünür Hill and in the surrounding area near Isparta. The city of Isparta is located between the latitudes of 37˚ 18´ N and 38˚ 30´ N. The height of Cünür Hill reaches about 1,090 m, and its geological exposure consists mainly of volcanic sand, limestone and alluvium [Görmüş and Özkul 1995, Yagmurlu et al. 1997, Nemec and Kazancı 1999, Görmüş et al. 2001, Francalanci et al. 2001]. This Isparta volcanic belongs to the post-collisional alkali potassic-ultrapotassic magmatism that has been active since the Miocene [Plateovet et al. 2008]. Figure 1 shows the location of Isparta within Turkey, and also the geological structure of Cünür Hill, near Isparta. The satellite view of the locations where the measurements were performed in the present study are shown in Figure 2. 2.2. Activity measurements A portable GF Instruments (Isparta,Turkey) c-ray spectrometer was used to measure the eU (ppm), eTh (ppm) and K (%) elemental concentrations. The spectrometer consisted of a NaI(Tl) scintillation detector connected to a 512-channel pulse-height analyzer. The detector size was ca. 5 cm × 5 cm and it was enclosed in a single integral unit with a photomultiplier tube, a high-voltage supply and a signal preamplifier. The calibration of the detector was carried out Article history Received May 17, 2010; accepted October 12, 2010. Subject classification: Isparta volcanics, Gamma-ray spectrometry, Potassium, Uranium, Thorium. 25 . A GROUND RADIOMETRIC STUDY 26 Figure 1. Geological map of Isparta [adapted from MTA 1997]. Figure 2. Satellite view of the study area and measurement locations. 27 using the 137Cs isotopic source that is mounted inside the probe. The natural radioactivity measurements were based on recording the quantities of the three natural long-lived elements: eU, eTh and K, based on their positioning at 1,760 keV, 2,610 keV and 1,461 keV respectively, in the energy spectrum. Table 1 gives the gamma-ray energies and emission rates for these nuclides [Baloguna et al. 2003]. Each of the measurements was performed at ca. 50 cm above the ground, for 5 min. 3. Results and discussions In-situ measurements were performed to obtain the mean elemental concentrations of eU, eTh and K for the different soil types in the Cünür Hill region. Overall, the results showed 13 ppm, 40 ppm and 2.4%, for eU, eTh and K, respectively. These data are given in Table 2 and illustrated in Figure 3, according to the alluvium deposits, and trachyandesitic and limestone soil types. As can be seen from Table 2 and Figure 3, the elemental concentrations vary across the different soil and rock types. The highest mean elemental concentrations were calculated from locations where there are trachyandesite outcrops, and the lowest mean concentrations were obtained from the limestone locations. The overall absorbed gamma dose rates in air due to the combined activities of these eU and eTh element series and K were also measured, using a GF Instruments survey meter. The data are shown in Table 2 according to the means within each soil type, and in Figure 4 for all of the individual locations, with the latter data ranging from 24.4 nGy/h to 218.4 nGy/h. For the trachyandesitic rock, the relative contribution to the dose due to the eTh element series is the greatest (73.5%), followed by the eU element series (21.9%) A GROUND RADIOMETRIC STUDY Figure 4. Absorbed dose rates across all of the sampling locations. Figure 3. Elemental concentrations for the three types of soil. Table 1. Natural radioactive elements analysed in this study. Table 2.Elemental concentrations, absorbed gamma dose rates and the an- nual effective doses determined, according to the soil types in the study area. Element Nuclide Half life Gamma-ray energy (keV) Emission rate 214Pb 26.8 min 295.2 19 238U 351.2 38.9 214Bi 19.9 min 609.3 43.3 1764.7 17 208Tl 3.05 min 583.2 185.77 232Th 2614.7 99.79 228Ac 6.13 h 911.1 22.7 40K 1.3×109 yr 1460.8 10.7 eU eTh K (ppm) (ppm) (%) (nGy/h) (mSv/y) Alluvium 10.3 25.8 1.94 148.2 0.18 Trachyandesite 11.2 39.3 2.31 191.9 0.23 Limestone 2.65 3.4 0.1 25.2 0.03 Soil type Elemental concentration Dose rate AEDR and K (4.6%). For the alluvium, this is similar: eTh with the greatest contribution for the gamma dose rate (71.7%), followed by the eU element series (23%) and K (4.3%). However, for the limestone, the relative contribution to the dose rate due to the eTh element series is lower, at 59.1%. The mapped combined gamma dose rate distribution according to the sample locations for Cünür Hill and the surrounding areas is shown in Figure 5. As can be seen from Figure 5, the highest gamma dose rate is at location 8, which is in the trachyandesite area, and the lowest is at location 47, which is in the limestone field. The low values for these combined gamma dose rates are seen especially to the north- east of Cünür Hill, which again will be due to the large occurrence of limestone in this area. This study area also includes trachyandesitic rock that forms the volcanic structure of Cünür Hill. It can be seen from Figure 4 and Figure 5 that the concentrations at the top of the hill are lower than those at other locations around the hill. This could be the result of the spreading of the trachyandesitic structure out of the hill, due to gravitation effects, and it might also due to meteorological effects on the soil characteristics. This could also be the result of using chemical materials on the cultivated land. The overall dose rate results classified according to the soil types on and around Cünür Hill are given in Table 2; as can also be seen from Figure 6, the soil that contains trachyandesite has higher dose rates than the other soil types. The annual effective dose rate (AEDR) is an important parameter for the evaluation of radiation hazards due to the absorption from these dose rates. Using the conversion coefficient from the absorbed dose in air to the effective dose (0.7 Sv/Gy) and 0.2 for the outdoor occupancy factor, which indicates that on average, 20% of our time all around the World is spent outdoors [UNSCEAR 2000], the AEDR was obtained from the following formula [Cevik et al. 2007, Turhan et al. 2008]: (1) The AEDR values obtained range between 0.03 and 0.74 mSv/y across all of the sampling locations. These data were combined according to the three soil types on and around Cünür Hill, and these mean values are given in Table 2 and illustrated in Figure 7. As can be seen, the values obtained are under the recommended limits of 1 mSv/y. These annual effective dose rates are also compared with the values obtained for other locations in other studies, as illustrated in Figure 8 [Orgun et al. 2005, Hafezi et al. 2005, Kilic and Aykamis 2009, Bozkurt et al. 2007]; as can be seen, all of these values are under the recommended limits. 5. Conclusion It can be concluded from the present study that as well as measurements of elemental concentrations, this radiometric method can be used for the mapping of geological fields. This helps to illustrate sources of the rock minerals in terms of the radioactivity revealed. On the other hand all of the values obtained in this study remain under the recommended values. To determine the radioactivity levels of Isparta as a region in Turkey, this type of study can be further enlarged from the Cünür area. A GROUND RADIOMETRIC STUDY 28 Figure 5. Absorbed dose rate distribution for Cünür Hill and its surroundings. AEDR (mSv/y) D (nGy/h) 8760 (h/y) 0.2 0.7 (Sv/Gy) 10 6 = = # # # # - 29 A GROUND RADIOMETRIC STUDY Figure 6. Absorbed dose rate classified according to soil type. Figure 7. Effective dose rate as a function of the soil types around Cünür Hill. Figure 8. Effective dose rates for the trachyandesitic rock in the present study in comparison with other published measurements: Tehran, Iran [Hafezi et al. 2005], the city of Isparta (present study), the town of Sivrihisar [Orgun et al. 2005], the province of Osmaniye [Kilic and Aykamis 2009], and the region of Saliurfa [Bozkurt et al. 2007]. Acknowledgements. This study was supported by the Suleyman Demirel University Research Foundation Unit (1913 D 09). References Akkurt, V. D. (2004). Isparta ve Çevresinin Dogal gamma Ra- dyasyonunun Ölçümü S.D.Ü. Fen Bil. Enstitüsü Dergisi 8-2, Special issue, 108. Aydin, I., M.S. Aydogan, E. Oksum and A. Koçak (2006). 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