Dynamics and interaction of zinc and boron with phosphorus in ultisol
By: Semsheer M.
Contributor(s): P Sureshkumar (Guide).
Material type:
BookPublisher: Vellanikkara Department of soil science and agricultural chemistry, College of horticulture 2015Description: 190 Pages.Subject(s): Soil science and agricultural chemistryDDC classification: 631.4 Online resources: Click here to access online Dissertation note: MSc Abstract: The recent soil fertility assessment of the entire state has revealed that more
than 60% of the soils in the state are having high P status due to continuous
application of P fertilizers like factomphos and bone meal. It was also established that
15% of the soils are deficient in zinc and about 60% of soils are deficient in boron.
Antagonistic interaction of P with zinc has already been well established. However
studies on interaction of P with boron are limited.
Thepresent study was undertaken in the above background in the Dept. of Soil
Science and Agricultural Chemistry during the period from 2013-2015 to understand
the chemistry, dynamics and bioavailability of zinc and boron with respect to the P
status of the soil, which in turn will help in modifying the fertilizer prescription in
terms of quantity and method of application of these nutrients.
In order to achieve the objective of elucidating the dynamics of Zn and B as
influenced by P status in lateritic soils and to optimize the level of P for balanced
nutrition of cowpea with respect to Zn and B, 18 lateritic soil samples (Ultisol), six
each coming under low, medium and high P status were identified from an initial 100
soil samples and characterized. A potculture experiment with cowpea as a test crop
was conducted in three soils, one each with low, medium and high average P status.
Soil and plant samples were collected at flowering and at harvesting stages and
analyzedfor nutrient content.
The distribution of fractions of inorganic P in the three soils showed that Fe
bound P was the dominant fraction contributing to more than 50% of the total
inorganic P. The soluble P fraction was about 6% in all the three soils. Fe and Al-P
were the main fractions contributing to the available pool initially.Among the
fractionsof boron, readily soluble boron recorded the lowest, where as the
contribution of residual boron was the highest.
Available P status in soils with low and medium P increased due to the
application of P while it decreased in soil with high P. The soil with high P soil
showed that the application of phosphorus lead to the fixation of phosphorus in to
insoluble forms whereas, if P was not applied there was solubilisation of Fe-P and Al-
P resulting in increased its availability. Plant adsorbed P from soluble P led to its
depletion at the end of vegetative phase. Applied P got transformed into Fe-P and Al-
P initially, which along with native occluded P got transformed to calcium bound P
which is contributing to the available pool at later stages. Application of Zn was
found to reduce Al-P and Fe-P due to the formation of insoluble zinc phosphate.
Application of Zn and B reduced the Ca-P, probably due to the formation of zinc
phosphate and Calcium borate.
In case of zinc fractions, water soluble + exchangeable fraction and organic
matter occluded zinc was directly contributing to the available pool. The other Zn
fractions except amorphous iron oxide occluded zinc were contributing to the
available pool indirectly through water soluble + exchangeable fraction. Application
of P reduced the water soluble + exchangeable zinc fraction where as the application
of boron enhanced the transformation of zinc into this fraction especially when boron
was applied without P. Application of P resulted in adsorption of zinc into
specifically adsorbed zinc.
With respect to boron fractions, readily soluble boron and oxide bound boron
were directly contributing to the available pool where as binding of boron with
organic matter as well as its transformation to residual boron reduced boron
availability. All the fractions of boron were contributing to available pool indirectly
through readily soluble fraction of boron. Application of phosphorus was found to
reduce the readily soluble boron due to anion competition. The applied boron either
remained in the soluble form or getting transformed to specifically adsorbed, oxide
bound, organic matter bund boron. Boron application along with P reduced the
readily soluble boron.
Application of Zn increased the Zn content in plant. However, the application
of P with and without B reduced the Zn content in plants. Application of P and Zn
reduced the boron content in plants and application of boron with and without
phosphorus recorded the highest boron content. The highest grain yield was recorded
in soil with medium P, while the high P status in soil either due to native P or due to
applied P reduced the yield resulting from induced lower uptake of zinc and boron.
Thus, at high levels of P, enough quantities of soluble zinc should be assured,
over and above the quantities of this element precipitated as zinc phosphate, both by
optimizing the pH and applying enough quantities of Zn. Similarly H3BO3 and
H2BO3
- ions should be enough to overcome competition from H2PO4
- ion at root
surface.
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|---|---|---|---|---|---|---|
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MSc
The recent soil fertility assessment of the entire state has revealed that more
than 60% of the soils in the state are having high P status due to continuous
application of P fertilizers like factomphos and bone meal. It was also established that
15% of the soils are deficient in zinc and about 60% of soils are deficient in boron.
Antagonistic interaction of P with zinc has already been well established. However
studies on interaction of P with boron are limited.
Thepresent study was undertaken in the above background in the Dept. of Soil
Science and Agricultural Chemistry during the period from 2013-2015 to understand
the chemistry, dynamics and bioavailability of zinc and boron with respect to the P
status of the soil, which in turn will help in modifying the fertilizer prescription in
terms of quantity and method of application of these nutrients.
In order to achieve the objective of elucidating the dynamics of Zn and B as
influenced by P status in lateritic soils and to optimize the level of P for balanced
nutrition of cowpea with respect to Zn and B, 18 lateritic soil samples (Ultisol), six
each coming under low, medium and high P status were identified from an initial 100
soil samples and characterized. A potculture experiment with cowpea as a test crop
was conducted in three soils, one each with low, medium and high average P status.
Soil and plant samples were collected at flowering and at harvesting stages and
analyzedfor nutrient content.
The distribution of fractions of inorganic P in the three soils showed that Fe
bound P was the dominant fraction contributing to more than 50% of the total
inorganic P. The soluble P fraction was about 6% in all the three soils. Fe and Al-P
were the main fractions contributing to the available pool initially.Among the
fractionsof boron, readily soluble boron recorded the lowest, where as the
contribution of residual boron was the highest.
Available P status in soils with low and medium P increased due to the
application of P while it decreased in soil with high P. The soil with high P soil
showed that the application of phosphorus lead to the fixation of phosphorus in to
insoluble forms whereas, if P was not applied there was solubilisation of Fe-P and Al-
P resulting in increased its availability. Plant adsorbed P from soluble P led to its
depletion at the end of vegetative phase. Applied P got transformed into Fe-P and Al-
P initially, which along with native occluded P got transformed to calcium bound P
which is contributing to the available pool at later stages. Application of Zn was
found to reduce Al-P and Fe-P due to the formation of insoluble zinc phosphate.
Application of Zn and B reduced the Ca-P, probably due to the formation of zinc
phosphate and Calcium borate.
In case of zinc fractions, water soluble + exchangeable fraction and organic
matter occluded zinc was directly contributing to the available pool. The other Zn
fractions except amorphous iron oxide occluded zinc were contributing to the
available pool indirectly through water soluble + exchangeable fraction. Application
of P reduced the water soluble + exchangeable zinc fraction where as the application
of boron enhanced the transformation of zinc into this fraction especially when boron
was applied without P. Application of P resulted in adsorption of zinc into
specifically adsorbed zinc.
With respect to boron fractions, readily soluble boron and oxide bound boron
were directly contributing to the available pool where as binding of boron with
organic matter as well as its transformation to residual boron reduced boron
availability. All the fractions of boron were contributing to available pool indirectly
through readily soluble fraction of boron. Application of phosphorus was found to
reduce the readily soluble boron due to anion competition. The applied boron either
remained in the soluble form or getting transformed to specifically adsorbed, oxide
bound, organic matter bund boron. Boron application along with P reduced the
readily soluble boron.
Application of Zn increased the Zn content in plant. However, the application
of P with and without B reduced the Zn content in plants. Application of P and Zn
reduced the boron content in plants and application of boron with and without
phosphorus recorded the highest boron content. The highest grain yield was recorded
in soil with medium P, while the high P status in soil either due to native P or due to
applied P reduced the yield resulting from induced lower uptake of zinc and boron.
Thus, at high levels of P, enough quantities of soluble zinc should be assured,
over and above the quantities of this element precipitated as zinc phosphate, both by
optimizing the pH and applying enough quantities of Zn. Similarly H3BO3 and
H2BO3
- ions should be enough to overcome competition from H2PO4
- ion at root
surface.
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