3. Results and discussion3.1. Conce

3. Results and discussion

3.1. Concentration of Cd in industrial soil

The individual data acquired for Cd in different soil samples are

shown in Table 1 in the year 2013 and 2014.The statistical analyses

are summarized as average, median and standard deviation. In

2013 the average concentration of Cd was 17.72 mg/kg, with a

maximum 28.20 mg/kg and a minimum 7.25 mg/kg in industrial

soil; the average concentration of Cd was 0.38 mg/kg, with a

maximum 2.37 mg/kg and a minimum 0.17 mg/kg in road side

sample; the average concentration of Cd was 0.78 mg/kg, with a

maximum 2.17 mg/kg and a minimum 0.14 mg/kg in field sample.

In 2014 the average concentration of Cd was 19.23 mg/kg, with a

maximum 29.75 mg/kg and a minimum 10.35 mg/kg in industrial

soil; the average concentration of Cd was 4.43 mg/kg, with a

maximum 6.68 mg/kg and a minimum 0.49 mg/kg in road side

sample; the average concentration of Cd was 1.79 mg/kg, with a

maximum 6.68 mg/kg and a minimum 0.41 mg/kg in field sample.

Thus in different types of soil samples the average amount of Cd

varies and follows the following order: industrial soil > road side

sample > field sample.

Guideline value for potentially toxic metal in various types of

soils, shale and water are given in Table 2 as prescribed by CCME,

1999. As the concentration of Cd was found to be: Industrial soil

(10.35–28.2 mg/kg); roadside soil (0.17–8.27 mg/kg); field soil

(0.14–6.85 mg/kg) and the maximum concentration of Cd in

different soil samples fall out of guideline values and exceeds

the permitted values. In other words, the concentration of Cd

exceeds the normally expected distribution in the soil give rise to

concern over the suitability of different type of soil [16]. There are

conflicting data in the literature concerning the level of Cd along

the vertical gradient of the soil. Khan and Frankland in 1983 [17]

observed no significant Cd beyond 10 cm, but Beavington in 1973

[18] reported predominant Cd in the top 15 cm. Our data

consistently demonstrated maximum concentration of 29.75 mg/

kg at 10 cm in the industrial soil, 5.71 mg/kg at 15 cm in the

roadside soil, 6.85 mg/kg at 5 cm in the field soil sample.

The average concentration of Cd exceeds the guideline value,

therefore, the soil of different sites are said to be polluted and its

source can be ascribed as a consequence of disposal of

anthropogenic hazardous waste. The maximum concentration of

Cd was found in the north sample (1.39 mg kg1

). The concentra-
tion of Cd in the north sample was found above the maximum

permissible limit (0.6 mg kg1

). In the present study, the maximum

concentration of Cd was found to be 28.2 mg/kg near site-CI. Cd in

nonagricultural soils generally not affect human health as it could

not enter the human food chain but its indirect transfer from

nonagricultural soil to agricultural soils via airborne or water

transport may affect the human health. Cd in agricultural soil is

relatively immobile but becomes mobile under acidic conditions.

The chemistry of Cd in soil is controlled by pH. Cd mobility

increases with the decreasing pH of the soil.

In the samples collected from industrial site (PFPL, CI, BCSI, PI);

roadside sample (RR1, RR2, RR3, RR4) and field sample (RF1, RF2,

RF3, RF4) showed following concentrations: the Cd concentration

was maximum mg/kg at site-CI in summer season and minimum

7.25 mg/kg at same site-CI in winter season in the year 2013–14;

the Cd concentration was maximum 6.85 mg/kg at site-RR1 in

winter season and minimum 0.71 mg/kg at site-RR2 in summer

season in the year 2013–14; the Cd concentration was maximum

6.85 mg/kg at site-RS1 in winter season and minimum 0.41 mg/kg

at site-RS1 in summer season in year 2013–14. The analytical

results indicate that the concentration of Cd was relatively more at

all sites in winter season than other two seasons. From the data it

has been concluded that industrial site has comparatively more Cd concentration than other sites and the comparative account for the

distribution of Cd concentration in different years is represented in

Fig. 2.

The pH of all samples was pH 7–9 (alkaline) at all sites. The

elevated pH of the soil in addition to rainfall event in the winter

season dilutes the soil solution more which increases the pH of

the soil. This increase in pH increases the ability of soil to adsorb

and fix Cd.