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Full Screen- TITLE
- SUPERVISORS CERTIFICATE
- DECLARATION
- ACKNOWLEDGEMENT
- DEDICATION
- CONTENTS
- 1.0 INTRODUCTION
- 1.1 Distribution
- 1.2 Classification
- 1.2.1 Trophic Classification
- 1.2.2 Ecological Classification
- 1.3 Influence of Environmental Factors on Earthworms
- 1.3.1 Moisture
- 1.3.2 Temperature
- 1.3.3 pH
- 1.3.4 Organic Matter
- 1.3.5 Soil type
- 1.4 Drilosphere
- 1.5 Physical Effects of Earthworms on Soils
- 1.5.1 Porosity
- 1.5.2 Water infiltration
- 1.6 Chemical effects of earthworms in soils
- 1.6.1 Influence on Soil Nitrogen
- 1.7 Biological Effects of Earthworms
- 1.8 Composting
- 1.8.1 Microbiological Aspects
- 1.9. Factors Affecting Composting
- 1.9.1 CN and CP Ratios
- 1.9.2 Other nutrients
- 1.9.3 Moisture
- 1.9.4 Aeration
- 1.9.5 Temperature
- 1.9.6 pH
- 1.9.7 Particle Size
- 1.10 Composting Methods and different forms of compost
- 1.10.1 Indore Method
- 1.10.2 Bangalore Process
- 1.10.3 NADEP Compost
- 1.10.4 Synthetic Compost
- 1.10.5 Leaf Compost
- 1.10.6 Accelerated Compost
- 1.10.7 Animal Waste Compost
- 1.10.8 Vermicompost
- 1.11 Earthworms and their effect on plant growth
- 1.12 Quality of compost
- 1.13 Regular Input Material
- 1.14 Present Investigation
- 2.0 MATERIALS AND METHODS
- 2.1 Collection of Earthworms
- 2.2 Collection of Organic. inputs
- 2.3 Experimental set up
- 2.3.1 Design of vermitech unit
- Plate 1
- 2.3.2 Preparation of vermibed
- PLATE 2 a) Megascolex konkanensis b) Drawida Species
- 2.4 Biological Parameters
- 2.5 Chemical Parameters
- 2.6 Calorific Content
- 2.7 Analysis of drain water from the vermitech unit
- 2.8 Microorganisms in casts
- 2.9 Pot Experiments
- 2.9.1 Experimental setup
- PLATE 3 Plants grown on composts from different inputs
- 2.9.2 Measurement of plant growth parameters
- 2.10 Statistical Methods of Analysis
- 2.11 Taxonomy
- 3.0 RESULTS
- 3.1 Vermitech experiments
- 3.2 Calorific content of inputs
- 3.3 Analysis of drained water from the vermitech unit
- 3.4 Microbial Succession
- 3.5 Pot experiments
- 3.5.1 Okra (Abelmoschus esculentus)
- 3.5.2 Brinjal (Solanum melongena)
- 3.5.3 Tomato (Lycopersicon esculentum)
- 3.6 Taxonomy
- ABBREVIATIONS - TABLES AND FIGURES
- TABLE 1 POPULATION DENSITY OF EARTHWORMS DURING THECOMPOSTING PROCESS (Nos. / 0.04 sq m)
- TABLE 2 BIOMASS OF EARTHWORMS DURING THE COMPOSTING PROCESS
- TABLE 3 MOISTURE (%) OF SOIL FROM VERMIBED DURING COMPOSTING PROCESS
- TABLE 4 pH OF SOIL FROM VERMJBED DURING COMPOSTING PROCESS
- TABLE 5 EC (mmhos) OF SOIL FROM VERMlBED DURING THE COMPOSTING PROCESS
- TABLE 6 ORGANIC CARBON (%) OF SOIL FROM VERMlBED DURING THE COMPOSTING PROCESS
- TABLE 7 TOTAL KJELDHAL NITROGEN (%) OF SOIL FROM VERMIBED DURING COMPOSTING PROCESS
- TABLE 8 AVAILABLE PHOSPHATE (P205%) OF SOIL FROM VERMlBED DURING COMPOSTING PROCESS
- TABLE 9 AVAILABLE POTASH (K20%) OF SOIL FROM VERMlBED DURING COMPOSTING PROCESS
- TABLE 10 COMPARISON OF NPK VALUES BEWEN REPETITIONS
- TABLE 11COMPARISON OF COMPOST WITH INITIAL SOIL (N, P, K VALUES)
- TABLE 12 % DECREASE OF C: N RATIO OF DIFFERENT INPUTS ON COMPOSTING
- TABLE 13 RANKING BASED ON % CHANGE IN NUTRIENTS ON BECOMING COMPOST
- TABLE 14 RANKING BASED ON NUTRIENT CONTENT IN COMPOST, NPK
- TABLE 15 COMPARISON OF NPK VALUES IN COMPOST HARVESTED FROM DIFFERENT INPUTS
- TABLE 16 CALORIFIC VALUE OF INPUTS
- TABLE 17 CORRELATION BETWEEN CALORIFIC VALUE OF INPUT WITH POPULATION DENSITY AND BIOMASS OF EARTHWORMS
- TABLE 18 ANALYSIS OF DRAINED WATER FROM VERMITECH
- TABLE 19 MICROBIAL SUCCESSION DURING VERMITECH FUNGUS X 103
- TABLE 20 MICROBIAL SUCCESSION DURlNG VERMITECHBACTERIA X 105
- TABLE 21 MICROBIAL SUCCESSION DURING VERMITECHACTINOMYCETES X 103
- TABLE 22 MICROBIAL SUCCESSION DURING VERMlTECHAZOTOBACTER X 102
- TABLE 23 MICROBIAL SUCCESSION DURING VERMITECH PHOSPHOBACTERIA X 103
- TABLE 24 COMPOSITE INDEX AND RANKING OF MICROORGANISMS BASED ON ABUNDANCE IN COMPOSTING UNIT
- TABLE 25 CORRELATION MATRIX OF MICROORGANISMS DURING THE COMPOSTING PROCESS WITH REFERENCE TO DIFFERENT INPUTS
- TABLE 26 CORRELATION MATRIX- SIGNIFICANCE (Table 25 -continued)
- TABLE 27 MULTIPLE CORRELATION AND SIGNIFICANCE OF MICROORGANISMS DURING THE COMPOSTINGPROCESS WITH REFERENCE TO DIFFERENT INPUTS
- TABLE 28 GROWTH PARAMETERS OF PLANTS GROWN ON COMPOST FROM DIFFERENT INPUTS
- TABLE 29 GROWTH PARAMETERS OF PLANTS GROWN ON COMPOST FROM DIITERENT INPUTS
- TABLE 30GROWTH PARAMETERS OF PLANTS GROWN ON COMPOST FROM DIFFERENT INPUTS
- TABLE 31 DAYS TAKEN FOR FRUITING AND YIELD (Mean Triplicates)
- TABLE - 36 A COMPARISON OF ANATOMICAL FEATURES OF D.ghatensis, D.nepalensis & D. trauencorensis
- Fig.1 Populaton density of earthworms
- Fig.2 Live biomass of earthworms
- Fig 3: MOISTURE IN VERMIRED
- Fig.4: pH
- Fig.5: EC
- Fig.6: ORGANIC CARBON
- Fig 7: TOTAL KJELDHAL NITROGEN
- Fig.8: AVAILABLE PHOSPHATE
- Fig.9: AVAILABLE POTASH
- Fig 10: MICROBIAL SUCCESSION DURING VERMITECH FUNGI
- Fig 11: MICROBIAL SUCCESSION DURING VERMITECH BACTERIA
- Fig 12: MICROBIAL SUCCESSION DURING VERMITECH ACTINOMYCETES
- Fig.13: MICROBIAL SUCCESSION DURING VERMITECH AZOTOBACTER
- Fig 14: MICROBIAL SUCCESSION DURING VERMITECH PHOSPHOBACTERIA
- Fig.15 A COMPARlSlON OF LEAF AREA. SHOOT LENSTHAND ROOT LENGTH IN THE GROWTH OF TOMATOGROWh ON COMPOST FROM DIFFERENT INPUTS
- 4.0 DISCUSSION
- 4.1 Vermitech experiments
- 4.2 Calorific value of feeds
- 4.3 Water drained out through vermibed
- 4.4 Microorganisms
- 4.5 Experiments on Plant Growth
- 4.6 Taxonomy
- TABLE 32 Taxonomical study of Drawida ghatensis Michaelsen, l910
- Drawida ghatensis
- TABLE 33 Taxonomical study of Drawida nepalensis Michaelsen, 1907
- Drawida nepalensis
- TABLE 34 Taxonornical study of Drawida travencorensis Michaelsen, l910
- Drawida travencorensis
- TABLE 35 Taxonornical study of Megascolex konkanensis Fedarb, 1898
- Megascolex konkanensis
- 5.0 CONCLUSION
- 6.0 RECOMMENDATIONS
- 7.0 SUMMARY
- 8.0 REFERENCES