3.1.5. Surface area of index leafTh

3.1.5. Surface area of index leaf
The average surface area of index leaf 5th that was 5th leaf
from the base of the plant 5.52±0.26 to 37.12±2.12cm2 (Table 1).
This surface area became bigger with the increasing strength of
wastewater. At the termination of the experiment, the surface
area in control (5.52cm2) was magnified by about 12 times in
100% wastewater (37.12cm2). The variances in surface area among
different strengths of wastewater and control were statistically significant
(one way ANOVA, P < 0.05; Tukey’s test, P < 0.05) except
between 100% and 50% wastewater treatments.
3.1.6. Chlorophyll-a and -b content in index leaf
The final average concentration of chlorophyll-a and -b in index
leaf (5th from base) is recorded in Table 1. In Chlorophyll-a, the
variations in the average concentration among different treatments
including control also were statistically significant (one way
ANOVA, P < 0.05; Tukey’s test, P < 0.05) except in between 100% and
50% wastewater treatments (Table 1) but in chlorophyll-b, the variations
among 50%, 75% and 100% were statistically insignificant
(one way ANOVA, P > 0.05). The responses in the concentration
of both chlorophyll-a and -b in index leaf were increased with
the strength of wastewater, though this concentration in both
decreased 10.92% and 6.25%, respectively, from 50% wastewater
treatment and 75% wastewater treatment{AQ}.
3.1.7. Biomass
The average root and shoot final dry mass ranged from
0.255±0.037 g to 1.889±0.341 g and 0.495±0.037 g to
5.921±0.214 g respectively in four treatments and in control
(Table 1). These dry biomasses were statistically distinct from
each other in both the cases (one way ANOVA, P < 0.05; Tukey’s
test, P < 0.05) except in-between the 50% and 75% wastewater
treatments for root and the 100% and 50% for shoot (Table 1). The
root mass tended to grow bigger up to 50%, but in turn, it started
to decline to extreme strength. By contrast, the shoot dry mass
increased with the strength of wastewater and the highest shoot
mass (5.921 g) was obtained in 100% wastewater, which was 12
times that of the control (0.495 g).
3.1.8. Nitrate reductase activity in root
Nitrate catalyzation by nitrate reductase (NR) enzyme
in root of tomato plant varying from 0.0521±0.001 to
0.8695±0.087MNO2 min−1 g tissue−1) was statistically
distinct in all strength of wastewater (one way ANOVA,
P < 0.05; Tukey’s test, P < 0.05) except between control
(0.1594MNO2 min−1 g tissue−1) and 75% wastewater treatment
(0.1594MNO2 min−1 g tissue−1) (Fig. 1). This rate was
accelerated to optimum (0.8695MNO2 min−1 g tissue−1) at
50% wastewater and in turn was decelerated to minimum
(0.0521MNO2 min−1 g tissue−1 with the further increase in