dc.description.abstract |
Atmospherically-derived natural (7Be,
210
Pb) and anthropogenic (137Cs) radioactive isotopes in
air, rain water and soil have been used to explore and understand the transport processes of
aerosols in the atmosphere and their subsequent removal from the atmosphere through wet
deposition to natural surfaces on the earth.
A systematic set of experiments were performed for the measurement of
210
Pb and 7Be
concentrations in the surface level air samples. The samples were collected on glass fibre filters
by using a portable air sampler at the Department of Physics, CIIT, Islamabad over an 18
months period (July 2007 to January 2009) and measured by employing the non-destructive
technique of γ-ray spectroscopy through N-type HPGe spectrometer. The annual average
surface air concentrations of
210
Pb and 7Be isotopes were determined to be 0.284±0.15 and
3.171±1.14 mBq m-3, respectively. The largest and smallest concentrations of
210
Pb were
observed in air masses approaching to the sampling point from the low lands with no forests
and forested high lands, respectively, showing its source region and interception of aerosols by
foliar surfaces. Concentrations of 7Be were found higher during spring season, consistent with
its stratospheric source region. Lower concentrations of both radionuclides were observed
during periods of high rainfalls, indicating that rain is a dominant removal agent of aerosols
from the atmosphere.
The activity and deposition rates of
210
Pb and 7Be isotopes were determined in the open rain
water and throughfall samples, collected from Murree, using γ-ray spectroscopy on HPGe
detector. Mean values of concentrations (annual deposition fluxes) of
210
Pb- and 7Be-bearing
aerosols, respectively, in open rain and throughfall samples were found as:
-1
-2
-1
7
-1
-2
210
-1
mBq.l (21.1 Bq m y ), Be: 572.9±201.4 mBq l (415.6 Bq m y ) and
Pb: 29.7±11.0
210
Pb: 16.7±6.3
mBq.l-1 (9.8 Bq m-2 y-1), Be: 441.74±321.04 mBq l-1 (294.56 Bq m-2 y-1). Concentrations and
deposition fluxes for both isotopes in open rain samples were found comparatively higher than
that of throughfall samples. Reduction of these quantities in throughfall samples is the
manifestation of the fact that rough surfaces of plantation leaves are effectively intercepting
radionuclides-bearing aerosols from the atmosphere. Seasonal trend in the concentrations of
both radionuclides, similar to air measurements, was observed with the lowest concentration of
210
Pb in summer season (consistent with soil as its origin and effectively washed out with rain
during the monsoon period in South Asia) and the highest concentration of 7Be in spring
season (consistent with stratospheric origin). A positive correlation between
210
Pb and 7Be
deposition was seen, indicating that these two isotopes can not be used as independent
atmospheric tracers. To see the effect of altitude, open rain samples only were also collected
from Islamabad during the period from September 2009 to October 2010. The annual mean
flux values of
210
Pb and 7Be here in the open lawn rain samples were found to be 1137 Bq m-2
y-1 and 3801 Bq m-2 y-1 respectively. The comparison of results from both sites showed higher
210
Pb and 7Be values for Islamabad and Murree respectively.
Activity concentrations and inventories of atmospherically deposited
210
Pb and
137
Cs
radionuclides in undisturbed woodland and adjacent open grassland soils were determined in
Islamabad and Murree regions. Based on our results, these values for the
210
Pb isotope were
found comparatively higher in samples collected under woodland soils than the soil samples of
open land, while, that of
137
Cs are higher in almost all samples collected from open land soils
compared to those samples collected under woodland soils. The depth profile of
210
Pb is
showing a decreasing trend in its activity along the depth in soils, with the maximum value at
the top (0-5 cm) layer of the soil, while
137
Cs activity in most samples was found maximum in
the 2nd (5-10 cm) and some times in 3rd (10-15 cm) layers, indicating that
137
Cs radionuclides
have been leached out to the deeper layers of soil with the passage of time.
Radon concentrations in drinking water, indoor air and soil gas samples collected from
Islamabad and Murree areas were measured by the active technique, using RAD-7 detector.
Higher radon concentrations were found in the water, indoor air and soil gas samples collected
from Islamabad region as compared to that from Murree region. Higher values of radon
concentration in water of Islamabad region were found consistent with the origin of radon
source (bore hole/well water) and the lower values in the samples of Murree region were
indicating the surface source of drinking water and the frequent flow of air at high altitude
sites. The contribution of mean annual effective doses from radon contained in the samples of
Islamabad and Murree regions were deduced and found lower than the recommended values of
UNSCEAR, ICRP and US EPA, thus posing no threat to the health of the local people.
In the last, the latent damage trails of fission fragments in CR-39 plastic detectors (exposed to
252
Cf source) were revealed through etching process, using various amounts of Na2CO3-mixed
6M NaOH solutions as etchants. Track etching parameters such as sensitivity, efficiency, etch
induction time, track and bulk etch velocities and track activation energies in the detector, were
determined. The results were compared with other similar studies and found with nice
agreement. The reduced etch induction times and activation energies in CR-39 detectors were
observed when etched them at 4% Na2CO3-mixed NaOH solution. Efforts were also made for
the fabrication of micro/nano filters in CR-39 detectors, to fractionate the size distribution of
aerosols. |
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