Factor 1: soil and building materia

Factor 1: soil and building material erosion
Factor 1 represents 44.6 % of the total variance. This
particular category consists of Na, Al, Si, Ca, Mg, K and
Fe. This factor represents the silica (Si, Al, Ca), feldspar
(Si, Al and K), silicates from building materials (Si, Al, Ca,
Fe; Si, Ca, Fe; Si, Ca; Si, Fe, etc.) and Ca and Mg carbonates.
These results were corroborated with the minerals
analyzed by XRD (Figs. 3 and 4). Thus, first category
belongs to soil and building material erosion.
SiO2 and aluminosilicates are the main types of silicon-
bearing particles observed in this study as analyzed
from the XRD study (Figs. 3 and 4). They both can be
assigned to natural and anthropogenic origin. Aluminosilicates
with spherical shapes come from anthropogenic
source and they could arise from combustion processes,
in contrast to irregularly shaped particles that are classified
as natural (earth’s crustal matter). Most of these are
seen in agglomerated consisting of the smaller particles
and enriched by the heavy metals as Fe, Cu and Zn. This
type of PM mainly originated from the construction
activities and industries. This is corroborated with the
ongoing construction and industrial activities in the
proximity of sampling site. In the present site, silicate
particles such as quartz are part of natural origin. Figure
6a shows SEM of the irregular particle with the high
percentage of Si, Al and O suggesting its origin from
geological and building materials, which have undergone
traffic-induced abrasion and re-suspension process. Figure
6b shows the smooth spherical particles along with its
elemental mapping. This smooth particle could be fly ash.
Fly ash is the byproduct of coal burning containing
mostly aluminosilicates (Chang et al. 1999). Li and Shao
(2009a) also suggest that particles contain Si, O and Al
with minor Ca, Ti, Mn and Fe as spherical fly ash. In
present study, elemental mapping also demonstrate that
particles are highly enriched with Al, Si, Ca along with
the Fe and Ti which implies that it is fly ash. In our
study, silicates contribute *52 % of the total minerals.
Silicate can act as greenhouse particles due to the fact
that the outgoing radiation is in the infrared and have
absorption bands in this wavelength (Rodriguez et al.
2009). High percentage of silicate mineral definitely
affects the climate of the city.
Calcium carbonates particles have also been frequently
observed in airborne PM sample (Ro et al. 2001; Li et al.
2003). In this study, presence of calcite (CaCO3) and
dolomite (Ca Mg (CO3)2) have also been identified by
XRD study (Fig. 3). These alkaline particles can absorb the
acidic gases such as SO2 and NO2 (Li and Shao 2009b) and
help to reduce the acidity of PM. Even though, percentage
contribution of this mineral is relatively very low. SEM
and EDS mapping results are shown in Fig. 7 where
qualitative identification of the elemental composition of
the particles of a selected area of the filter paper showed
the distribution of the Ca, C and O along with some Si
particles implies the presence of CaCO3. The SEM
micrograph in Fig. 7 showed that the particle on the filter
paper tend to form large conglomerates of smaller Ca
particles interspersed with the significant amounts of C and
O. The elemental EDS scan also showed the amount of Si
in very small particles. Presence of these minerals in Pune
City may be due to the site, which is covered with the
rocky hills.
The presence of halite in the PM of Pune can be
explained by the proximity of the sea. Halite and other sea
particles are important light scatterers and efficient condensation
nuclei and they provide large surface area for
atmospheric reactions.