PRODUCTION OF LIQUID BIOFERTIZER AND BIOCHEMICAL CHARACTERISATION OF COMPONENT NITROGEN-FIXING AND PHOSPHATE-SOLUBILISING BACTERIA SPECIES | Blazingprojects Postgraduate Thesis
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PRODUCTION OF LIQUID BIOFERTIZER AND BIOCHEMICAL CHARACTERISATION OF COMPONENT NITROGEN-FIXING AND PHOSPHATE-SOLUBILISING BACTERIA SPECIES

 

Table Of Contents


Chapter ONE

INTRODUCTION

  • 1.1Introduction
  • 1.2Background of Study
  • 1.3Problem Statement
  • 1.4Objective of Study
  • 1.5Limitation of Study
  • 1.6Scope of Study
  • 1.7Significance of Study
  • 1.8Structure of the Research
  • 1.9Definition of Terms

Chapter TWO

LITERATURE REVIEW

  • 2.1Overview of Liquid Biofertilizer
  • 2.2Importance of Nitrogen-Fixing Bacteria
  • 2.3Role of Phosphate-Solubilising Bacteria
  • 2.4Biochemical Characterization of Bacteria Species
  • 2.5Previous Studies on Biofertilizers
  • 2.6Sustainable Agriculture and Biofertilizers
  • 2.7Application Methods of Liquid Biofertilizers
  • 2.8Challenges in Biofertilizer Production
  • 2.9Innovations in Biofertilizer Technology
  • 2.10Future Trends in Biofertilizer Research

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Methodology Overview
  • 3.2Selection Criteria for Bacteria Species
  • 3.3Isolation and Culturing Techniques
  • 3.4Biochemical Analysis Procedures
  • 3.5Testing for Nitrogen-Fixing Abilities
  • 3.6Testing for Phosphate-Solubilising Abilities
  • 3.7Data Collection and Analysis Methods
  • 3.8Quality Control Measures

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Analysis of Bacteria Species Characteristics
  • 4.2Nitrogen-Fixing Potential Evaluation
  • 4.3Phosphate-Solubilising Efficiency Assessment
  • 4.4Comparison with Standard Biofertilizers
  • 4.5Impact of Bacteria Species on Plant Growth
  • 4.6Environmental Effects of Liquid Biofertilizer
  • 4.7Economic Considerations in Biofertilizer Production
  • 4.8Recommendations for Further Research

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Findings
  • 5.2Conclusions Drawn from the Study
  • 5.3Implications for Agriculture and Environment
  • 5.4Contribution to Scientific Knowledge
  • 5.5Practical Applications of Research Results
  • 5.6Limitations and Future Research Directions
  • 5.7Recommendations for Implementation
  • 5.8Conclusion and Final Remarks

Thesis Abstract

A

NTRODUCTION

1.1. BACKGROUND

Geometric increase in world population, coupled with effects of global warming/climate change, have had deteriorative effects on agricultural productivity. With an estimated 815 million people undernourished in the world today (FAO, 2017), it is necessary to take fervent steps to improve agricultural productivity. Such steps could include improving seed quality, germination conditions, farming practices and soil quality.

Soil quality can be improved by the use of fertilizer, which can either be of chemical or biological sources. Chemical fertilizers have been in popular use since the 20th century, especially since their contribution to the Third Agricultural (Green) Revolution.

However, excessive and extensive use of chemical fertilizers have resulted in a large number of environmental problems (Savci, 2012); which include water, soil and air pollution. Nitrate content from chemical fertilizers can get into water bodies by drainage, leaching, and flow. This cause eutrophication, leading to algal bloom and suffocation of aquatic life. Also, chemical fertilizers contain heavy metals, such as cadmium and chromium. As such, long-term use may result to accumulation of inorganic compounds in the soil, degrading its quality. Continuous use of chemical fertilizers effects soil degradation and deterioration of soil fertility. This is as it affects soil pH, usually with negative effects on soil organisms, such as worms, soil mite.

Chemical fertilizers also contribute to air pollutions during evaporation of ammonia (NH3) from ammonia fertilizer; which may be oxidized to nitric acid, and cause acid rain. Also, emissions of nitrogen oxides (NO, N2O, NO2) contribute to global warming and climate change.

1


These detriments of chemicals propagated concerns on the best approach to increase agricultural productivity, while protecting the environment.

The advent of biofertilizer has served to counter the deleterious effects of chemical fertilizers, while being more advantageous. Biofertilizer is commonly referred to as the fertilizer that contains living micro-organisms and it is expected that their activities will influence the soil ecosystem and produce supplementary substance for the plants (Parr et. al., 2002). They contain live and efficient formulates of bacteria, algae and fungi either separately or in combination that are capable of fixing atmospheric nitrogen, solubilising phosphorus, decomposing organic materials or oxidising sulphur and; on application will enhance the availability of nutrients for the benefits of the plants (Hanapi et. al., 2012). They also accelerate certain microbial processes in the soil which augment the extent of availability of nutrients in a form easily assimilated by plants.

The first generation of commercial biofertilizer – ‘Nitragin’ – was developed in 1895 by Nobbe and Hiltner, from nitrogen-fixing rhizobacteria isolated from legumes; followed by the discovery of Azotobacter, then the blue green algae and a host of other microorganisms (Ghosh, 2003; Gavrilescu & Chisti, 2005).

Based on formulation, biofertilizers can be either solid or liquid (Chandra  et. al.,  2005).

1.2. STATEMENT OF PROBLEM

Among the crop nutrients, nitrogen as well as phosphorus and potassium play important roles in increasing the crop productivity (Pindi & Satyanarayana, 2012). Biofertilizers provide an effective alternative to chemical fertilizers. However, with the short shelf-life and high risk of contamination encountered with solid biofertilizers, liquid biofertilizers serve as a better option.

2


Also, there is need to identify and confirm the component microorganisms of biofertilizer; to assist subsequent research into ways of optimising their performance.

1.3. AIM

This project is aimed at producing a liquid biofertilizer from readily available fruit and plant sources; and basically, identify and characterise the component nitrogen-fixing and phosphate-solubilising bacteria species.

1.4. OBJECTIVES

·         Production of liquid biofertilizer

·         Isolation of bacteria from the biofertilizer

·         Biochemical identification and characterisation of component nitrogen-fixing and phosphate-solubilising bacteria species.

BSTRACT

Excessive use of chemical fertilizers have caused a large number of environmental pollution in water, air and soil. Biofertilizers have, therefore, been developed as a safer and more effective alternative. Biofertilizers refer to any substance that contains living organisms whose activities can improve the plant growth by increasing availability of plant nutrients. This work is aimed at production of liquid biofertilizer using fruits, rice chaff, wheat chaff and soil containing growth-promoting microorganisms; as well as isolation and characterisation of the component nitrogen-fixing and phosphate-solubilising bacteria. Azotobacter and Bacillus subtilis were isolated using Mannitol Ashby and Pikovskaya agar media, respectively. They were characterised using biochemical tests. This can be used in further research to genetically engineer these organisms, in order to optimise their efficiency.


Thesis Overview

<p> </p><div><p><strong>NTRODUCTION</strong></p><p><strong>1.1. BACKGROUND</strong></p><p>Geometric increase in world population, coupled with effects of global warming/climate change, have had deteriorative effects on agricultural productivity. With an estimated 815 million people undernourished in the world today (FAO, 2017), it is necessary to take fervent steps to improve agricultural productivity. Such steps could include improving seed quality, germination conditions, farming practices and soil quality.</p><p>Soil quality can be improved by the use of fertilizer, which can either be of chemical or biological sources. Chemical fertilizers have been in popular use since the 20th century, especially since their contribution to the Third Agricultural (Green) Revolution.</p><p>However, excessive and extensive use of chemical fertilizers have resulted in a large number of environmental problems (Savci, 2012); which include water, soil and air pollution. Nitrate content from chemical fertilizers can get into water bodies by drainage, leaching, and flow. This cause eutrophication, leading to algal bloom and suffocation of aquatic life. Also, chemical fertilizers contain heavy metals, such as cadmium and chromium. As such, long-term use may result to accumulation of inorganic compounds in the soil, degrading its quality. Continuous use of chemical fertilizers effects soil degradation and deterioration of soil fertility. This is as it affects soil pH, usually with negative effects on soil organisms, such as worms, soil mite.</p><p>Chemical fertilizers also contribute to air pollutions during evaporation of ammonia (NH3) from ammonia fertilizer; which may be oxidized to nitric acid, and cause acid rain. Also, emissions of nitrogen oxides (NO, N2O, NO2) contribute to global warming and climate change.</p><p>1</p></div><p><br></p><div><p>These detriments of chemicals propagated concerns on the best approach to increase agricultural productivity, while protecting the environment.</p><p>The advent of biofertilizer has served to counter the deleterious effects of chemical fertilizers, while being more advantageous. Biofertilizer is commonly referred to as the fertilizer that contains living micro-organisms and it is expected that their activities will influence the soil ecosystem and produce supplementary substance for the plants (Parr <em>et. al.,</em>&nbsp;2002). They contain live and efficient formulates of bacteria, algae and fungi either separately or in combination that are capable of fixing atmospheric nitrogen, solubilising phosphorus, decomposing organic materials or oxidising sulphur and; on application will enhance the availability of nutrients for the benefits of the plants (Hanapi <em>et. al.,</em>&nbsp;2012). They also accelerate certain microbial processes in the soil which augment the extent of availability of nutrients in a form easily assimilated by plants.</p><p>The first generation of commercial biofertilizer – ‘Nitragin’ – was developed in 1895 by Nobbe and Hiltner, from nitrogen-fixing rhizobacteria isolated from legumes; followed by the discovery of Azotobacter, then the blue green algae and a host of other microorganisms (Ghosh, 2003; Gavrilescu &amp; Chisti, 2005).</p><p>Based on formulation, biofertilizers can be either solid or liquid (Chandra &nbsp;<em>et. al.,</em>&nbsp; 2005).</p><p><strong>1.2. STATEMENT OF PROBLEM</strong></p><p>Among the crop nutrients, nitrogen as well as phosphorus and potassium play important roles in increasing the crop productivity (Pindi &amp; Satyanarayana, 2012). Biofertilizers provide an effective alternative to chemical fertilizers. However, with the short shelf-life and high risk of contamination encountered with solid biofertilizers, liquid biofertilizers serve as a better option.</p><p>2</p></div><p><br></p><p>Also, there is need to identify and confirm the component microorganisms of biofertilizer; to assist subsequent research into ways of optimising their performance.</p><p><strong>1.3. AIM</strong></p><p>This project is aimed at producing a liquid biofertilizer from readily available fruit and plant sources; and basically, identify and characterise the component nitrogen-fixing and phosphate-solubilising bacteria species.</p><p><strong>1.4. OBJECTIVES</strong></p><p>· &nbsp; &nbsp; &nbsp; &nbsp; Production of liquid biofertilizer</p><p>· &nbsp; &nbsp; &nbsp; &nbsp; Isolation of bacteria from the biofertilizer</p><p>· &nbsp; &nbsp; &nbsp; &nbsp; Biochemical identification and characterisation of component nitrogen-fixing and phosphate-solubilising bacteria species.</p> <br><p></p>

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