Radiological Risk Assessment in Soil Samples of Western Haryana, India
The measurements of 226Ra, 232Th and 40K using
gamma spectrometry and radon concentration and exhalation rates
measurements using solid state nuclear track (LR-115, Type-II
plastic) detectors are used to asses a first order exposure risk for the
persons residing in Fatehbad and Hissar districts of Western Haryana,
India. The concentration of Radium, Thorium and Potassium in the
soil samples varies from 13.37 Bq m-3 to 24.67 Bq m-3, 34.67 Bq m-3
to 67.34 Bq m-3 and 298.78 Bq m-3 to 405.67 Bq m-3 respectively
with average values of 18.78, 47.35 and 361.57 Bq m-3 respectively.
The radium equivalent activity (Raeq) calculated for the same soil
samples varies from 92.72 Bq m-3 to 140.6 Bq m-3 with an average
value of 111.80 Bq m-3. The values of absorbed dose and annual
effective dose (indoors and outdoors) are found to vary from 44.18
nGy h-1 to 65.23 nGy h-1, 0.22 mSv y-1 to 0.32 mSv y-1 and 0.05 mSv
y-1 to 0.08 mSv y-1 respectively. The radon concentration and
exhalation rates have also been reported. The radium equivalent
activities in all the soil samples were found to be lower than the limit
(370 Bq kg-1) set in the Organization for Economic Cooperation and
Development (OECD) report and the value of Hex in all the samples
is less than unity.
[1] A.P. Radhakrishna, H.M. Somasekarapa, Y. Narayana, K. Siddappa, "A
new natural background radiation area on the southwest coast of
India", in Health Physics, vol. 65, pp. 390-395, 1993.
[2] L.S. Quindos, P.L. Fernandez, J. Soto, C. Rodenos, J. Gomez, "Natural
radioactivity in Spanish soils", in Health Physics, vol. 66, pp.194-200,
1994.
[3] R. Mehra, S. Singh, K. Singh, "A study of uranium, radium, radon
exhalation rate and indoor radon in the environs of some areas of
Malwa region, Punjab", in Indoor and Built Environment, vol. 15(5),
pp. 499-505, 2006.
[4] R. Mehra, S. Singh, K. Singh, R. Sonkawade, "226Ra, 232Th and 40K
analysis in soil samples from some areas of Malwa region, Punjab,
India using gamma ray spectrometry", in Environ Monit Assess, vol.
134, pp. 333-342, 2007.
[5] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Sources and Biological Effects.
New York: United Nations. 1994.
[6] D.L. Henshaw, J.P. Eatough, R.B. Richardson, "Radon as a causative
factor in induction of myeloid leukemia and other cancers", in Lancet,
vol. 355, pp.1008-1015, 1990.
[7] R.C. Ramola, R.B.S. Rawat, M.S. Kandari, T.V. Ramachandran, K.P.
Eappen, M.C. Subba Ramu, "Calibration of LR-115 plastic track
detectors for environmental radon measurements", in Indoor Built
Environ, vol. 5, pp.364-366, 1996.
[8] F. Abu-Jarads, J.H. Fremlin, R. Bull, "A study of radon emitted from
building materials using plastic alpha track detectors", in Phys Med
Biol., vol. 25, pp. 683-694,1980.
[9] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Effects and risks of ionizing
radiations. New York: United Nations. 2000.
[10] M.V. Nageswara Rao, S.S. Bhatti, P. Rama Seshu, A.R. Reddy, "
Natural radioactivity in soil and radiation levels of Rajasthan" in
Radiat Prot Dosim, vol. 63(3), pp. 207-216, 1996.
[11] Organization for Economic Cooperation and Development., Exposure to
radiation from the natural radioactivity in building materials. Paris:
Report by a group of experts of the OECD Nuclear Energy Agency.
1979.
[12] S. Singh, R. Mehra, K. Singh, "Uranium, Radium and Radon Exhalation
Studies in Soil Samples Belonging to Some Areas of Punjab, Using
Track Etching Technique" in Journal of Environment Science and
Engineering, vol. 47(2), pp. 85-90, 2005.
[13] R. Kaul, K .Umamaheshwar, S. Chandrashekharan, R.D. Deshmukh,
B.M. Swarmukar, "Uranium mineralization in the Siwaliks of North
Western Himalayan, India", in Journal of Geological Society of India,
vol. 41, pp. 243-258, 1993.
[14] K.N. Yu, Z.J. Guan, M.J. Stoks, E.C. Young, "The assessment of
natural radiation dose committed to the Hong Kong people" in Journal
of Environmental Radioactivity, vol.17, pp. 31-35, 1992.
[15] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Sources and Effects of Ionizing
Radiation. New York: United Nations. 1993.
[16] D.C. Kocher, A.L. Sjoreen, "Dose-rate conversion factors for external
exposure to photon emitters in soil", in Health Physics, vol. 48, pp.193-
205, 1985.
[17] P. Jacob, H.G. Paretzke, H. Rosenbaum, M. Zankl, "Effective dose
equivalents for photon exposure from plane sources on the ground", in
Radiat Prot Dosim, vol. 14, pp.299-310, 1986.
[18] K.C. Leung, S.Y. Lau, C.B. Poon, "Gamma radiation dose from
radionuclides in Hong Kong soil", in Journal of Environmental
Radioactivity, vol. 11, pp. 279-290, 1990.
[19] International Commission on Radiological Protection,. Limits for intake
of radionuclides by workers. Oxford: Pergamon Press; ICRP Publication
65, Ann ICRP 23(2). 1993.
[20] J. Beretka, P.J.Mathew, "Natural radioactivity of Australian building
materials, industrial wastes and by-products" in Health Physics vol. 48,
pp. 87-95, 1985.
[21] European Commission. Radiation Protection, Radiological protection
principles concerning the natural radioactivity of building materials.
European Commission 112, 1999.
[22] T.V. Ramachandran, M.C. Subba Ramu, "Estimation of indoor
radiation exposure from the natural radioactivity content of building
materials" in Oncol, vol. 3, pp. 20-25, 1989.
[23] K.H. Folkerts, G. Keller, R. Muth, "An experimental study of diffusion
and exhalation of 222Rn and 220Rn from building materials", in Radiat
Prot Dosim, vol. 9, pp.27-34, 1984.
[1] A.P. Radhakrishna, H.M. Somasekarapa, Y. Narayana, K. Siddappa, "A
new natural background radiation area on the southwest coast of
India", in Health Physics, vol. 65, pp. 390-395, 1993.
[2] L.S. Quindos, P.L. Fernandez, J. Soto, C. Rodenos, J. Gomez, "Natural
radioactivity in Spanish soils", in Health Physics, vol. 66, pp.194-200,
1994.
[3] R. Mehra, S. Singh, K. Singh, "A study of uranium, radium, radon
exhalation rate and indoor radon in the environs of some areas of
Malwa region, Punjab", in Indoor and Built Environment, vol. 15(5),
pp. 499-505, 2006.
[4] R. Mehra, S. Singh, K. Singh, R. Sonkawade, "226Ra, 232Th and 40K
analysis in soil samples from some areas of Malwa region, Punjab,
India using gamma ray spectrometry", in Environ Monit Assess, vol.
134, pp. 333-342, 2007.
[5] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Sources and Biological Effects.
New York: United Nations. 1994.
[6] D.L. Henshaw, J.P. Eatough, R.B. Richardson, "Radon as a causative
factor in induction of myeloid leukemia and other cancers", in Lancet,
vol. 355, pp.1008-1015, 1990.
[7] R.C. Ramola, R.B.S. Rawat, M.S. Kandari, T.V. Ramachandran, K.P.
Eappen, M.C. Subba Ramu, "Calibration of LR-115 plastic track
detectors for environmental radon measurements", in Indoor Built
Environ, vol. 5, pp.364-366, 1996.
[8] F. Abu-Jarads, J.H. Fremlin, R. Bull, "A study of radon emitted from
building materials using plastic alpha track detectors", in Phys Med
Biol., vol. 25, pp. 683-694,1980.
[9] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Effects and risks of ionizing
radiations. New York: United Nations. 2000.
[10] M.V. Nageswara Rao, S.S. Bhatti, P. Rama Seshu, A.R. Reddy, "
Natural radioactivity in soil and radiation levels of Rajasthan" in
Radiat Prot Dosim, vol. 63(3), pp. 207-216, 1996.
[11] Organization for Economic Cooperation and Development., Exposure to
radiation from the natural radioactivity in building materials. Paris:
Report by a group of experts of the OECD Nuclear Energy Agency.
1979.
[12] S. Singh, R. Mehra, K. Singh, "Uranium, Radium and Radon Exhalation
Studies in Soil Samples Belonging to Some Areas of Punjab, Using
Track Etching Technique" in Journal of Environment Science and
Engineering, vol. 47(2), pp. 85-90, 2005.
[13] R. Kaul, K .Umamaheshwar, S. Chandrashekharan, R.D. Deshmukh,
B.M. Swarmukar, "Uranium mineralization in the Siwaliks of North
Western Himalayan, India", in Journal of Geological Society of India,
vol. 41, pp. 243-258, 1993.
[14] K.N. Yu, Z.J. Guan, M.J. Stoks, E.C. Young, "The assessment of
natural radiation dose committed to the Hong Kong people" in Journal
of Environmental Radioactivity, vol.17, pp. 31-35, 1992.
[15] UNSCEAR, United Nations Scientific Committee on the Effects of
Atomic Radiation. Ionizing Radiation: Sources and Effects of Ionizing
Radiation. New York: United Nations. 1993.
[16] D.C. Kocher, A.L. Sjoreen, "Dose-rate conversion factors for external
exposure to photon emitters in soil", in Health Physics, vol. 48, pp.193-
205, 1985.
[17] P. Jacob, H.G. Paretzke, H. Rosenbaum, M. Zankl, "Effective dose
equivalents for photon exposure from plane sources on the ground", in
Radiat Prot Dosim, vol. 14, pp.299-310, 1986.
[18] K.C. Leung, S.Y. Lau, C.B. Poon, "Gamma radiation dose from
radionuclides in Hong Kong soil", in Journal of Environmental
Radioactivity, vol. 11, pp. 279-290, 1990.
[19] International Commission on Radiological Protection,. Limits for intake
of radionuclides by workers. Oxford: Pergamon Press; ICRP Publication
65, Ann ICRP 23(2). 1993.
[20] J. Beretka, P.J.Mathew, "Natural radioactivity of Australian building
materials, industrial wastes and by-products" in Health Physics vol. 48,
pp. 87-95, 1985.
[21] European Commission. Radiation Protection, Radiological protection
principles concerning the natural radioactivity of building materials.
European Commission 112, 1999.
[22] T.V. Ramachandran, M.C. Subba Ramu, "Estimation of indoor
radiation exposure from the natural radioactivity content of building
materials" in Oncol, vol. 3, pp. 20-25, 1989.
[23] K.H. Folkerts, G. Keller, R. Muth, "An experimental study of diffusion
and exhalation of 222Rn and 220Rn from building materials", in Radiat
Prot Dosim, vol. 9, pp.27-34, 1984.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:60920", author = "R. Mehra", title = "Radiological Risk Assessment in Soil Samples of Western Haryana, India", abstract = "The measurements of 226Ra, 232Th and 40K using
gamma spectrometry and radon concentration and exhalation rates
measurements using solid state nuclear track (LR-115, Type-II
plastic) detectors are used to asses a first order exposure risk for the
persons residing in Fatehbad and Hissar districts of Western Haryana,
India. The concentration of Radium, Thorium and Potassium in the
soil samples varies from 13.37 Bq m-3 to 24.67 Bq m-3, 34.67 Bq m-3
to 67.34 Bq m-3 and 298.78 Bq m-3 to 405.67 Bq m-3 respectively
with average values of 18.78, 47.35 and 361.57 Bq m-3 respectively.
The radium equivalent activity (Raeq) calculated for the same soil
samples varies from 92.72 Bq m-3 to 140.6 Bq m-3 with an average
value of 111.80 Bq m-3. The values of absorbed dose and annual
effective dose (indoors and outdoors) are found to vary from 44.18
nGy h-1 to 65.23 nGy h-1, 0.22 mSv y-1 to 0.32 mSv y-1 and 0.05 mSv
y-1 to 0.08 mSv y-1 respectively. The radon concentration and
exhalation rates have also been reported. The radium equivalent
activities in all the soil samples were found to be lower than the limit
(370 Bq kg-1) set in the Organization for Economic Cooperation and
Development (OECD) report and the value of Hex in all the samples
is less than unity.", keywords = "Gamma ray spectrometry, dose, radon, exhalationrate.", volume = "3", number = "6", pages = "440-5", }
