and 164.3–331.8 Bq/kg for40K. For b

and 164.3–331.8 Bq/kg for
40
K. For bottom ash radioactivities in a
coal-fired power plant in Hong Kong, Tso and Leung (1996)
reported an average value of 100 Bq/kg for
226
Ra, 105 Bq/kg for
232
Th and 132 Bq/kg for
40
K.Pandit et al. (2011)reported lower
values of radioactivities in bottom ash (45 Bq/kg for
226
Ra, 40 Bq/
kg for
232
Th and 20 Bq/kg for
40
K), performing a study at three
different coal-fired power plants in India.Gur and Yaprak (2010)
reported considerably higher radioactivities in bottom ash (ranging from 213 to 1098 Bq/kg for
226
Ra, 7–122 Bq/kg for
232
Th and
67–585 Bq/kg for
40
K), conducting a study in several coal-fired
power plants in western Turkey.
Surface soil samples S1–S4 were taken near to the coal-fired
power plant, the AC of
226
Ra in samples S1 and S2, at some 87 Bq/
kg, being found to be significantly higher than the world range 35
(17–60 Bq/kg) for
226
Ra (UNSCEAR, 2000). In the absence of any
other known mechanisms except the natural background, it is
likely that these represent disturbed soils affected by deposited
fly-ash in dominant wind directions. The AC for
226
Ra in S3, a
location close to a large scale garbage dumping site, showed the
highest value (see inFig. 2) among all soil samples, likely to have
resulted from disturbed and contaminated soil artificially turned.
The AC for
232
Th and
40
K in samples S1–S4 were also found to be
higher than the world averages (30 Bq/kg for
232
Th, 400 Bq/kg for
40
K) for these radionuclides (UNSCEAR, 2000), again being
expected to be associated withfly-ash deposition in these particular locations.
Table 7
Accumulated doses (mSv) via ingestion and inhalation after 30 years of intake under several conditions. Average activity (Bq) of the studied radionuclides and the respective
dose conversion factors were used to calculate the yearly committed effective dose inmSv.
Sample type Sample code Activity intake (Bq) Dose via Ingestion (mSv/30 years) Dose via Inhalation (mSv/30 years)
226
Ra
232
Th
40
K Extreme
Intake (100%)
Intake (50%) Intake (10%) Extreme
Intake (100%)
Intake (50%) Intake (10%)
Ash/Slag S 51.774.1 40.273.8 108.679.6 21.0 10.5 2.1 6100 3100 610
Surface soil S1 46.573.8 39.973.6 159.9712.5 20.0 10.0 2.0 6100 3100 610
S2 46.473.8 35.373.1 149.5711.7 19.0 9.5 1.9 5400 2700 540
S3 64.275.4 36.273.2 185.2715.9 23.0 11.5 2.3 5600 2800 560
S4 30.172.7 26.672.2 166.3714.8 14.0 7.0 1.4 4100 2050 410
S5 33.572.8 29.072.7 154.9712.7 15.0 7.5 1.5 4400 2200 440
S6 20.571.7 11.071.1 114.879.7 7.4 3.7 0.7 1700 850 170
S7 21.671.7 24.272.3 150.9713.0 11.0 5.5 1.1 3700 1850 370
S8 22.171.6 16.171.3 104.679.6 9.0 4.5 0.9 2500 1250 250
S9 21.871.9 16.771.4 108.679.2 9.1 4.5 0.9 2600 1300 260
S10 36.872.7 31.872.9 171.2714.9 16.0 8.0 1.6 4800 2400 480
S11 29.372.5 34.173.1 191.2716.2 15.0 7.5 1.5 5200 2600 520
S12 25.172.3 23.472.2 156.2714.1 12.0 6.0 1.2 3600 1800 360
S13 36.072.8 23.772.2 158.7714.2 14.0 7.0 1.4 3600 1800 360
S14 55.974.9 27.972.4 193.6717.8 19.0 9.5 1.9 4300 2150 430
S S1 S2 S3 S4 S5 S6 S7 S8 S9 S10 S11 S12 S13 S14
20
40
60
80
100
120
140
Kapar town
Junction of a highway
School compound area
Radiation indices
Sample code
226
Ra (Bq/kg)
232
Th (Bq/kg)
Dex
(nGy/h)
Near CPP and garbage dumping area
Bottom ash at CPP
Fig. 2.Activity concentrations (Bq/kg) of Uranium and Thorium radionuclides and
external gamma-ray dose rate in air (nGy/h) at the studied regions.
Table 6
Accumulated ingestion and inhalation doses (mSv) after 1 year of intake under several conditions. Average activity (in Bq) of the studied radionuclides (Eq. (1)) and the
respective dose conversion factors (Table 5) were used to calculate yearly committed doses.
Sample type Sample code Activity intake (Bq) Dose via Ingestion (mSv/yr) Dose via Inhalation (mSv/yr)
226
Ra
232
Th
40
K Extreme
Intake (100%)
Intake (50%) Intake (10%) Extreme
Intake (100%)
Intake (50%) Intake (10%)
Ash/Slag S 51.774.1 40.273.8 108.679.6 4.2 2.1 0.42 220 110 22.0
Surface soil S1 46.573.8 39.973.6 159.9712.5 4.1 2.0 0.41 210 100 21.0
S2 46.473.8 35.373.1 149.5711.7 4.0 2.0 0.40 190 97 19.0
S3 64.275.4 36.273.2 185.2715.9 5.3 2.7 0.53 240 120 23.0
S4 30.172.7 26.672.2 166.3714.8 3.0 1.5 0.30 140 69 14.0
S5 33.572.8 29.072.7 154.9712.7 3.2 1.6 0.32 150 76 15.0
S6 20.571.7 11.071.1 114.879.7 2.0 1.0 0.20 72 36 7.2
S7 21.671.7 24.272.3 150.9713.0 2.3 1.2 0.23 110 57 11.0
S8 22.171.6 16.171.3 104.679.6 2.1 1.0 0.21 91 45 9.1
S9 21.871.9 16.771.4 108.679.2 2.1 1.0 0.21 92 46 9.2
S10 36.872.7 31.872.9 171.2714.9 3.5 1.7 0.35 170 83 17.0
S11 29.372.5 34.173.1 191.2716.2 3.1 1.6 0.31 160 79 16.0
S12 25.172.3 23.472.2 156.2714.1 2.6 1.3 0.26 120 59 12.0
S13 36.072.8 23.772.2 158.7714.2 3.3 1.6 0.33 140 70 14.0
S14 55.974.9 27.972.4 193.6717.8 4.8 2.4 0.48 190 95 19.0
Y.M. Amin et al. / Applied Radiation and Isotopes 80 (2013) 109–116 114
Sample S5 shows average ACs of 63.7 Bq/kg, 55.0 Bq/kg, and
293.8 Bq/kg for
226
Ra,
232
Th and
40
K, respectively, for thefirst two
radionuclides being rather higher than that for S4 (see inFig. 2). The
samples were taken near to a school compound, it being supposed
that in addition tofly-ash fall out, the soil resulted from a mixture of
native soil with slag in connection with building activity.
The mean AC values for samples S6–S9 showed a decreasing
trend, and were also similar in values to the world averages. These
samples were taken from outside the inhabited area, i.e., the
grassland within rural territories, undisturbed by anthropomorphic activities.
Samples S10 showed a higher mean AC (see inFig. 2) for the
studied radionuclides than the world averages, the location being
in the vicinity of a large construction activity and near to the
junction of a highway, with possible consequent soil turnover
effects. Conversely, samples S11–S12 were taken within a palm oil
estate approaching the edge of Kapar town. The averages AC for
the studied radionuclides were lower in values than those for S10
samples albeit with slightly higher values than the world averages.
The surface soil samples S13 and S14 were collected inside
Kapar town, both sets of samples showing rather higher mean ACs
for the studied radionuclides. Here, slag has been mixed with
topsoil as landfill. Other anthropomorphic activities including
building can also be expected to have contributed to the outcome.
For the radium equivalent activity (Raeq), all but one set of
surface soil samples showed mean values higher than the world
average for soil (89 Bq/kg); the exception, sample set S6, concerns
soil collected from inhabited and rural grass land areas. All
samples were found to have an equivalent activity of o370 Bq/
kg corresponding to a radiation dose of 1.5 mSv/yr. The greatest
value of activity was for the bottom-ash samples, at 315.6 Bq/kg.
In general, the trend of Raeqin the soil samples was found to
mirror the mean ACs, as did the calculated external gamma-ray
dose rate (D) for the samples. The ash samples showed the highest
average dose rate with 143.3 nGy/h, whereas surface soil collected
near the power plant (S3) showed the highest dose rate associated
with soil, at 112.1 nGy/h. The calculated committed effective doses
for the studied samples followed the similar trend to their average
activities as presented inTables 6and7. The highest committed
effective dose in the case of soil samples was found for the
activities measured in surface soil samples S3 (collected near to
the power plant), while samples S6 (collected from inhabited and
rural grass land areas) showed the lowest. The maximum committed effective dose for the respective S3 soil samples was
projected to be 5.3mSv for 1 year of ingestion, 240mSv for 1 year
of inhalation, 23mSv for 30 years of ingestion and 5.6 mSv for 30
years of inhalation, obtained assuming that all the radionuclides
were taken in by adults. Even under extreme intake situations the
accumulated doses would still be very small, as for example
220mSv and 6.1 mSv for inhalation intake of pure bottom ash
following a period of exposure of 1 year and 30 years, respectively