EG0600055 Proceedings of the Environmental Physics Conference, 24-28 Feb. ~ — , -.„..,.„, -OJr
-RN-222 RELEASE TO THE ENVIRONMENT: COMPARISON
BETWEEN DIFFERENT GRANITE SOURCES
A. Mamoon and Salah M. Kamal
Radiation Protection Department, Nuclear Research Center (NRC), Atomic Energy Authority (AEA), Cairo, P.O. Box 13759,Cairo, Egypt
E- mail: [email protected]
ABSTRACT
In this work three different types of granites were studied, namely: pure granite, alkali granite and altered (hydrated) alkali granite. General radioactivity of the granites was studied along with the potential for 222Rn emanation. The study
indicated that altered alkali granite releases, relatively, the highest 222Rn emanation
to the surrounding air while alkali granite emits the more intense gamma radiation of the three granites. Hence, altered alkali granite can be used as a laboratory source fox 222Rn.
INTRODUCTION
Granites- of different types are known to contain traces of uranium ^]'2\ Among the decay products of uranium is Ra which in turn decays to 222Rrij which being a gas, leaks out
from the mother rock and can escape to the atmosphere or dissolve in surrounding surface or ground water '•3"4l Hence granites can serve as convenient laboratory scale source for studies
2 2 2 ^
on Rn.
The present work conducts a comparative study of the general radioactivity characteristics and 2 2 2 ^ emanation capability of three different types of granite, namely: pure granite, alkali granite and altered (hydrated) alkali granite [5]. The aim of the study is to
select the granite source with the greatest potential for emanating Rn[6].
MATERIALS AND METHODS
Samples from the three granite rocks were crushed to 2mm particle diameter. Equal masses (250g each) of the crushed granites were placed in two containers; in either Marinelli beakers for gamma spectroscopy using HPGe detector, or in emptied charcoal canisters for measuring the surface dose to TLD-200. The dosimeters were positioned on top of the crushed source as shown in (Fig. 1).
Proceedings of the Environmental Physics Conference, 24-28 Feb. 2004, Minya, Egypt
TLD chips 3 layers of Vinyl tape
Fig. 1. Diagrammatic representation of TLD chips placed on surface of granite rock filling an emptied canister
222 The two containers were closed tight for four weeks before making the measurements.
Rn emanation assay was carried out using standard charcoal canister technique. The granite rocks along with an open regular charcoal canister were placed, one by one, in a confined exposure desiccator (regular laboratory system) for three days. Measurements of the
222
emanated Rn air concentrations (for the three granite rocks) in the desiccator air were carried out using standard charcoal counting technique.
RESULTS AND DISCUSSION
Equal masses of the crushed granites, having the same mesh number, were used in all the experiments. While gamma spectra of the granites showed similarities of the many gamma energies present yet there was variation in the relative intensities of some gamma lines as shown in (Fig. 2). For example, in the case of alkali granite, this has an increased level of potassium, the 40K gamma line being more intense. While, 214Pb and Bi gamma energies
were present in all granites at about the same intensities.
The gross gamma count rates (table 1) of the granites show as expected, that alkali granite gave the highest count rate. The dose rate at the surface of the crushed granites, as measured by TLD-200, was highest for alkali granite (Fig. 3) namely about 460DR/hour compared to about 28DR/hour for pure granite. For altered alkali granite, the mass used, i.e. 250 grams, has water as part of the used mass. This is reflected in the less surface dose rate compared to alkali granite. Increasing the mass of altered alkali granite used (Fig. 4) showed,
Proceedings of the Environmental Physics Conference, 24-28 Feb. 2004, Minya, Egypt
. 2 1 4 Bl - 214 K
-Fig. 2. Gamma-ray spectra detected by HPGe detector for different types of granite collected: (a) alkali granite (b) altered alkali granite and (c) pure granite. Notice presence of 40K in all granites but at different relative concentrations. 214Pb and 214Bi (222Rn daughters) main energy peaks are present in all granites. The counting time was 72000 sec.
The results indicate that, as a laboratory source for 222R1 1 J altered alkali granite seems
to be the better granite to use in such situations.
Table 1. Comparison between the three different granite types in terms of gross counts of selected region of interest around energy peaks of radon daughters (2 1 4Pb and 214Bi) to be
analyzed _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
IL
No. 1 2 3 Granite Type* Alkali Altered alkali Pure Region of Interest Gross Count 10,105,028 3,036,139 612,414s
Dos e 500-400 300-200 100-0 OSeriesi / control 2.68 Pure Granite 27.97sLJ
Altered Alkali 121.13 Al Gr1
1
I
J
kali anite 462.83r
Fig. 3. The dose-rate as measured by TLD chips placed on top of 250 grams of different granite rocks having 2.0 mm particle diameter, the control is an empty canister.
I
o QM
|r.
-
-ri-
-j
I
0 . 0Mass of Altered Alkali Granite Rocks ( g )
Fig. 4. Dose-rate measured by TLD chips Placed On top of different masses of granite rock having 2.0 mm particle diameter.
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Proceedings of the Environmental Physics Conference, 24-28 Feb. 2004, Minya, Egypt
REFERENCES
[1] Crameri, R.; Brunner, H. H.; Buchli, R.; Wemli, C. and Brkart, W., "Indoor Rn Levels in Different Geological Areas in Switzerland," Health Physics Vol. 57, No. 1, pp. 29-38, July, 1989.
[2] Buch, R. and Burkart, W., "Influence of Subsoil Geology and Construction Technique on Indoor Air Rn-222 Levels in 80 Houses of the Central Swiss Alps," Health Physics Vol. 56, No. 4, pp. 423-429, April, 1989.
[3] Saito, K.and Jacob, P.: "Gamma ray fields in the air due to sources in the ground". Radiation Protection Dosimetry Vol. 58, No. 1, pp. 29 - 45 (1995)
[4] Luetzelschwals, J.W.; heleeick, K. L. and Hurst, K. A., "Radon Concentration in Five Pennsylvania Soils." Health Physics Vol. 56, No. 2, pp. 181-188, Feb., 1989.
[5] Sextro, R.G.; Moed, B.A.; Nazaroff, W.W.; Revzan, K.K. and Nero, A.V., "Investigations of Soil as a Source of Indoor Radon", American Chemecal Socity Symposium Series No. 331, cited by Philip K. Hopke, 1987.
[6] BEIR, "Health effects of exposure to Radon", National Academy Press, Washington D.C., BEJR VI, Committee on Health Risks of Exposure to Radon, (1999).
[7] Anjos, R.M.; Veiga, R.; Soares, T.; Santos, A.M.A.; Gguiar, J.G; Frasca, J.A. P.; Uzeda, D.; Mangia, L.; Facure, A.; Nosquera, B.; Carvalho, C. and Gomes, P.R.S.; " Natural Radiohuclide Distribution in Brazilian Commercial Granites ", Radiation Measurements, Vol. 05, No. 002, pp. 1-14,14 July, 2004.
