The effect of light intensity on th

The effect of light intensity on the vegetative growth of an
okra cultivar (‘Clemson spine’) on the field
The effect of light intensity on the vegetative growth of
the okra cultivar (‘Clemson spine’) selected from the pot
experiment on the field was similar to what was observed in
the pot. The highest values for plant height, number of leaf,
leaf area and number of fruits were recorded in plants grown
under 76% light reduction (L3). This treatment was
significantly (P < 0.05) different from other treatments while
control (0% reduction) had the least value. In respect to days
to flower, okra plants under L0 commenced flowering earlier
than those ones under light reductions (Table 7). Similarly,
on the field, okra growth responded positively to compost
application. The plant height was increased in soil amended
with compost most especially at the rate of 15 t/ha followed
by that of 5 t/ha. The least mean was recorded in the control
where there was no addition of compost. Also, number of
leaf was more in okra plants treated with 15 t/ha (C3) which
also had the highest value followed by those treated with 5
t/ha and the least mean was recorded in the control (no
compost). However, in respect of day to flower, there was a
delay in those grown in compost amended soil compared to
control. The effect of compost application on the leaf area
and number of fruit was also remarkable though not
statistically significant, and plant treated with 15 t/ha had the
highest leaf area and number of fruit followed by C1
treatment, while the least value was recorded in the control
(Table8)
Interactive effect of compost application and light intensity
on the vegetative growth of okra on the field
Generally, across the treatments for light intensity
interacting with compost application, the highest mean
values were recorded in the plants treated with 37.5 g or 15

t/ha compost. The interactive effect of compost application
and light intensity was more significant under 76% light
reduction and highest compost application (L3 x C3). There
were increases in plant height, leaf area, number of leaf and
fruit compared to control and other treatments. There were

no significant (P < 0.05) differences in the interaction
between compost application and high light intensity, though
the interaction reveals that mean height and number of fruit
increased in plants treated with 12.5 g or 5 t/ha of compost
compared to L0 x C0 and L0 x C3, which had smaller values.

Normal light (L0) interacting with compost at all levels
showed that plants treated with 12.5 g or 5 t/ha had the
highest mean values for plant height and number of leaf and
fruit, while the least were recorded in the control (no
compost). 33% light intensity (L1) interacting with 15 t/ha
compost also had the highest mean for plant height, number
of leaf, leaf area and number of fruit. The interactive effect of
compost and light intensity on days to flower showed that the
plants under normal light (no light reduction) and no
compost (C0) had the least mean across the treatments,
which means that flowering was hastened under this light
intensity, while the plants grown under low light intensity
(L3= 76%) and 15 t/ha compost had the highest mean across
the treatments though there were no significant differences
among the means. Moreover, the interactive effect of
compost application and light intensity on leaf area showed
that okra plants grown under high light intensity or no light
reduction (L0) had the least mean values compared to the
other light treatments. Whereas, plant with low light
intensity (33 and 76% light reduction) and 15 t/ha of
compost had the highest mean (Table 9).
The effect of compost application and light intensity on the
yield parameters of okra on the field
Though, under low light intensity (76% light reduction
L3) there was an increase in the fruit fresh and dry weight
compared to other means recorded, but the effect of light
intensity on the yield parameters of okra in the field generally
showed that there was no significant (P < 0.05) difference
among all the parameters measured, except for root fresh and
dry weight. Compost application however had significant
effect on all yield parameters compared to the control, with
higher compost rate performing better than lower rate. The
fresh weight was significantly (P < 0.05) higher in plant
treated with 15 t/ha compost (Table 10). The interactive
effect of light intensity and various levels of compost
application on the yield parameters showed that plants
treated with compost at 15 t/ha had the highest value under
various light intensity. Application of 15 t/ha of compost
increased the fresh and dry weight of okra and the lowest was
recorded in the control. Furthermore, across the treatment
the interaction between varying level of light intensity (L0,
L1, L3) and compost (C0, C1, C2) on the fresh fruit weight
showed that the highest fresh fruit weight was recorded under
low light intensity (L3 = 76% light reduction) with 15 t/ha of
compost, while the lowest mean was recorded under the
normal light intensity (L0, control) without compost (C0,
control) (Table 11).
Discussions
The effect of compost and light intensity in both trials
showed that the performance of okra was generally improved
with the application of compost and reduction in the light
intensity. This was reflected in the interactive effect of compost
application and light intensity on the growth and yield
parameters of okra. At high light intensity where the plants
were exposed to intense rays of light, which probably might
have also increased the rate of transpiration in plants, but with
the application of compost, the stress effect of excessive heat
was minimized. Rather, there was an increase in growth and
yield parameters compared to control. The ability of compost
to enrich the soil with required nutrients definitely contributed
significantly to the yield of okra under varying light intensities
(Akande et al., 2004; Ojeniyi and Olamilua, 2005; Premsekhar
and Rajashree, 2009). Compost also has the ability to increase
the soil water holding capacity which in-turn could have
enhanced the water balance in the soil (Adediran et al., 2004;
Sanwal et al., 2007).
Differences were however observed in the response of okra
in the pot and field experiments. The observation on the field
showed that the effect of light on okra growth was more
pronounced than what was recorded in the pot experiment. In
the pot, 33% reduction in light intensity, produced more fruits,
76% light reduction also reduced the number of days to flower
whereas leaf area and number of leaf were not affected. On the
field, leaf area, plant height, number of leaf and number of
fruits were enhanced under reduced light intensity (76%
reduction) contrary to what was found in the pot experiment.
This was not surprising, as plants generally perform and
respond to treatments under field (natural) conditions better
than when cultivated in pots where their growth and potentials
are restricted. The positive effect of shade (reduction in light
intensity) on leaf area and number of leaf on the field however
contradicted other reports where shade reduced leaf area
formation as well as number of leaf (Wilson and Coope, 1969).
Reduction in light intensity prolonged the number of days to
flower and this agreed with the previous report that light
reduction reduces the rate of photosynthesis, which in turn
would have affected the growth and developmental processes
(Grabau et al., 1990). Growth of pollen tube was reportedly
impaired with reduction in light intensity, thereby delaying
fertilization and fruiting (Campbell et al., 2001) as observed in
this study. The okra plants grown under reduced light
intensities were still fruiting later than those ones under high
light intensity have started shedding their leaves. This
accounted for the increase in number of fruits recorded in
reduced light intensities despite the fact that those under 100%
light intensity started fruiting earlier. Excessive light intensity
has been reported to scorch/burn the leaves and reduce crop
yields (Edmond et al., 1978). It also reduces the chlorophyll
content, which in turn reduces the rate of light absorption and
the rate of photosynthesis. This is because excess light intensity
is associated with increase in the temperature of leaves and this
will lead to rapid transpiration and water loss. The guard cells
are said to lose turgor. The stomata are also partially or
completely closed and the rate of diffusion of carbon dioxide
into the leaves slows down (Wilson and Coope, 1969). The
rate of photosynthesis decreases while respiration continues,
resulting in low availability of carbohydrates for growth and
development. The high leaf temperature also inactivates all the
enzymatic system, especially those that changes sugars to starch.
Physiologically, an increase in the accumulation of sugar in the
stroma of chloroplast prevents or slows down photosynthesis.
Similarly, compost effect was not significant on the growth
parameters in the pot whereas, on the field, plant height,
number of leaf, number of flower and leaf area increased
significantly with increase in compost rates irrespective of light
intensity and crop variety. Under high light intensity however,
compost application was a relieve, probably due to the
scorching effect of high light intensity as revealed by the
performance of treated okra in terms of all the vegetative
parameters compared to control (L0C0). The variation in the
response of okra varieties to the light intensity and compost

amendments could be due to their genetic make- up because
crop response to different growth managements is a factor of its
genetic compositions (Aladele et al., 2008; Manjanbu et al.,
1986; Odeleye et al., 2005). ‘Clemson’ in particular has been
reported to respond positively both to fertilizer amendments
and different light intensities (Kansal et al., 1981; Knorr and
Vogtmann, 1983;