Aquatic environmental bioengineering : monitoring and remediation of contamination / Rouf Ahmad Bhat, Mohammad Yaseen Mir, Gowhar Hamid Dar, Moonisa Aslam Dervash.

By: Bhat, Rouf Ahmad, 1981- [author.]
Contributor(s): Yaseen Mir, Mohammad [author.] | Dar, Gowhar Hamid [author.] | Dervash, Moonisa Aslam [author.]
Language: English Publisher: Hoboken, NJ : John Wiley & Sons, 2022Copyright date: ©2022Description: 1 online resource : illustrations (chiefly color)Content type: text Media type: computer Carrier type: online resourceISBN: 9781119760948; 9781119760979; 1119760976; 9781119760962; 1119760968; 9781119760955; 111976095XSubject(s): Water -- Purification | Water -- PollutionGenre/Form: Electronic books.Additional physical formats: Print version:: Aquatic environmental bioengineeringDDC classification: 628.1/62 LOC classification: TD430 | .B47 2022Online resources: Full text available at Wiley Online Library Click here to view
Contents:
Table of Contents Preface xi About the Authors xii 1 Emerging Pollutants Remediation Water Systems: Biomass-Based Technologies 1 1.1 Introduction 1 1.2 Adsorption-Based Remediation 3 1.2.1 Biomass 3 1.2.2 Terrestrial and Marine Bioresources 3 1.2.3 Agro-Industrial Wastes 3 1.2.4 Activated Carbons (ACs) 4 1.2.5 Bioresources 4 1.2.6 Agro-Industrial Wastes 4 1.2.7 Activated Sludge (AS) 4 1.3 Bioremediation 4 1.3.1 Phytoremediation 4 1.3.2 Constructed Wetlands (CWs) 5 1.3.3 Microbial Remediation 5 1.3.4 Biocoagulants and Bioflocculants 5 1.4 Multi-Element Water Treatment Process 1 1.4.1 Membrane Bioreactors (MBRs): Biodegradation and Membrane Filtration 6 1.4.2 Activated Carbon and Ozone 7 1.5 Views and Recommendations 7 1.6 Conclusion 7 2 Genetic Engineering for Metal Tolerance and Accumulation 12 2.1 Introduction 12 2.2 Mechanisms of Metal Uptake and their Transport in Plants 14 2.2.1 Heavy Metals Tolerance (Mechanism) in Plants 15 2.2.2 Mechanisms of Avoidance in Plants 15 2.2.3 Binding of Metal to the Cell Wall 16 2.2.4 Mechanisms of Tolerance in Plants 16 2.3 Phytoremediation Using Genetic Engineering Stress-Tolerant Plants 18 2.3.1 Selenium Accumulation by Plants 20 2.3.2 Genetics of Plants Selenium Accumulation 21 2.3.3 Proteins for Metal Accumulation 24 2.4 Genetically Modified Plants Against Uptake, Tolerance and Detoxification of Heavy Metals 24 2.5 Cadmium Tolerance and Accumulation Mechanisms in Plants 26 2.5.1 Immobilization 27 2.5.2 Chelation Using Organic Acids and Amino Acids 27 2.5.3 Stress Peptide Synthesis 27 2.5.4 Cd Transporters 28 2.5.5 Genetic Analysis of Cadmium Tolerance and Accumulation in Plants 28 2.6 Heavy Metal ATPases (HMA) 30 3 Transgenic Approaches for Field Testing and Risk Assessment 42 3.1 Introduction 42 3.2 Transgenic Plants for Environmental Remediation 43 3.3 Degradation Pathways in Plants 44 3.4 Cytochrome P450s for Environmental Perspectives 44 3.5 Transgenic Plants for the Rhizoremediation of Organic Xenobiotics 45 3.6 Transgenic Plants to be Developed for the Phytoremediation of Some Other Priority Pollutants 46 3.7 Potential Genes for Phytoremediation 47 3.8 Hitting Transgenics to the Assessment: Plant Bioremediation 49 3.9 Potential Risks 50 3.9.1 Risk Assessment Theories and Practices 50 3.9.2 Contests Aimed at Multifaceted Risk Valuation 51 3.10 Future Research Guidelines 51 4 Role of RS and GIS in Water Quality Monitoring and Remediation 59 4.1 Introduction 59 4.2 Scope of RS and GIS in Water Monitoring 60 4.3 Assessment of Certain Impurities in Water With the Aid of RS and GIS 61 4.3.1 Suspended Load 61 4.3.2 Phytoplankton 62 4.3.3 Turbidity 62 4.4 Benefits of RS in Assessment of Water Quality 63 4.4.1 Soil Moisture Mapping for Floods and Droughts 63 4.4.2 Spatially Distributed Crop Water Use Estimation 64 4.4.3 Surface Water Quality Monitoring and Remediation 64 4.4.4 Groundwater Quality Monitoring and Remediation 65 4.5 Future Prospectus of RS and GIS Applications in Water Quality Studies 66 5 Advancement on Bioaugmentation: Strategies for Processing Industry Wastewater 71 5.1 Introduction 71 5.2 Present Disposal Techniques and their Limitations 73 5.3 Bioaugmentation as an Emerging Strategy 73 5.3.1 Bioaugmentation Principle 75 5.3.2 Cell Bioaugmentation 75 5.3.3 Biological Augmentation as a Tool for Improving the Wastewater Treatment Efficiency 75 5.3.4 Role of Bioaugmentation in Removing Recalcitrant Pollutants from Industrial Wastewater 76 5.4 Bioaugmentation Applications 76 5.4.1 Removal of Compounds 76 5.4.2 Removal of Lignin 77 5.4.3 Pyridine and Quinoline 77 5.4.4 Cyanides 78 5.4.5 Nicotine 78 5.5 Bioaugmentation Technologies and their Limitations 78 5.5.1 Grazing of Protozoans 79 5.5.2 Inoculum Size 79 5.5.3 Bacteriophage Infection 79 5.6 Strategies for Improving the Effectiveness of Bioaugmentation 80 5.6.1 Immobilizing the Cells in Bioaugmentation 80 5.6.2 Quorum Sensing 80 5.6.3 Gene Transfer and Genetically Modified Microorganisms 81 5.7 Bioaugmentation and Nanotechnology 81 5.8 Future Prospects 82 5.9 Conclusion 82 6 Photocatalysis in Relation to Water Remediation 89 6.1 Introduction 89 6.2 Characteristics of Material 93 6.2.1 Homogeneous Photocatalysis 93 6.2.2 Heterogeneous Photocatalysis 94 6.3 Consequence of Ultra Violet/Titanium Dioxide/Hydrogen Peroxide 95 6.3.1 Chlorophenol 95 6.3.2 2, 4-Dichlorophenol 95 6.3.3 2, 4, 6- Trichlorophenol 96 6.4 Obstacles for Applicability 97 6.4.1 Advancement of Photocatalytic Materials 97 6.4.2 Photocatalytic Reactor Design and System Evaluation 97 6.5 Strategies for Improving Research Outcomes 98 7 Biochemical Systems: Cathode Advanced Wastewater Treatment 103 7.1 Introduction 103 7.2 Cathodic Catalysis in BES and Implications for Catalyst Design 104 7.2.1 Cathodic Catalysis Characteristic in BES 104 7.2.2 Operation Environment 105 7.2.3 Wastewater Electrolyte 105 7.2.4 Cathode Over Potential and Catalysis in BES 106 7.2.5 Photo-Aided Cathodic Catalysis 106 7.3 Wastewater Treatment 107 7.3.1 Highly Biodegradable Wastewater 107 7.3.2 Complex/Low Biodegradable Wastewater 107 7.3.3 Integrated Process for Additional Treatment 108 7.4 Current Bottlenecks and Challenges for BES 108 7.5 Future Directions 111 8 Nanotechnology: Environmental Sustainable Solutions for Wastewater Treatment 116 8.1 Introduction 116 8.2 Water Nanotechnology 118 8.2.1 Adsorption and Separation 118 8.2.2 Catalysis 118 8.2.3 Disinfection 119 8.2.4 Sensing 119 8.2.5 Carbon-Based Nanoadsorbents 119 8.2.6 Metal-Based Nanoadsorbents 120 8.2.7 Polymer-Based Nanoadsorbents 121 8.3 Zeolites 121 8.4 Magnetic Nanocomposites 122 8.5 Nano Zero Valent Iron (nZVI) 122 8.6 Biosorbents 123 8.7 Treatment of Wastewater by Means of Membrane-based Techniques 124 8.8 Nanoparticles for Microbial Control and Disinfection 125 8.9 Antimicrobial Action of Nanoparticles 126 8.10 Potential Applications in Wastewater Treatment 127 8.11 Benefits of Nano-Biotechnology-Based Applications for Water Sustainability 127 8.12 Challenges and Future Outlook 128 9 Biotechnology Intercession in Phytoremediation 138 9.1 Introduction 138 9.2 Genetically Engineered Plants and Phytoremediation 138 9.3 Qualitative Phytoremediators 141 9.4 Biotechnology in Plant Mediated Remediation for Contaminants 141 9.5 Toxic Metals (TMs) 141 9.5.1 Arsenic (As) 142 9.5.2 Mercury (Hg) 143 9.5.3 Organic Pollutants (OPs) 143 9.5.4 Pesticides 144 9.5.5 Oil Spills (OSs) 144 9.6 Conclusion and Future Prospects 145 10 Biofilms in Remediation: Current Trends and Future Perspectives 150 10.1 Introduction 150 10.2 Different Methods for Culturing Biofilms In Vitro 152 10.2.1 Static Microtiter Plate Assays 152 10.2.2 Tube Biofilms 152 10.2.3 Colony Biofilms 152 10.2.4 Biofilm Growth on Peg Lids 153 10.2.5 Rotating Disk and Concentric Cylinder Reactors 153 10.5 Methods for Characterization of Biofilms 154 10.5.1 Confocal Laser Scanning Microscopy (CLSM) 154 10.5.2 Scanning Electron Microscopy (SEM) 155 10.5.3 Atomic Force Microscopy (AFM) 155 10.5.4 Infrared and Raman Spectroscopy 155 10.5.5 X-ray Spectroscopy 155 10.5.6 Nuclear Magnetic Resonance (NMR) Spectroscopy 155 10.6 Biofilm-Based Bioremediation 156 10.7 Nitrogen Fixing Microorganisms in Lakes 158 10.8 Conclusion 159 11 Graphene-Based Absorbents for Wastewater Treatment 164 11.1 Introduction 164 11.2 Graphene-Based Materials 165 11.3 Graphene–Polymer Composites 165 11.4 Applications of Graphene as an Adsorbent in Water Remediation 170 11.4.1 Polycyclic Aromatic Hydrocarbons (PAHs) 171 11.4.2 Phenolic Compounds 172 11.4.3 Pharmaceutical Compounds 173 11.4.4 Pesticides 173 11.4.5 Dyes 174 11.5 Future Scope 175 12 Sewage Sludge: Use in Agriculture Practices 181 12.1 Introduction 181 12.2 Characteristics of Sewage Sludge 18 12.3 Activation of Sewage Sludge 183 12.4 Disposal of Sludge to Land 184 12.5 The Effect of Sludge Application on Soil Properties 185 12.5.1 Physico-Chemical Properties 185 12.5.2 Microbial Parameters of Soil 188 12.5.3 Concentration of Nutrients and the Heavy Metals in Sewage Sludge and Soil 191 12.6 Outlines of Nutrients and Harmful Metals in Sludge and Soil 192 12.7 The Accumulation of Nutrients by Crops 193 12.8 Future Views 194 13 Microbial Fuel Cells for the Treatment of Wastewater 203 13.1 Introduction 203 13.2 Biochemical Sustenance of Microbes 204 13.3 Functioning of MFCs 204 13.3.1 Uses of MFCs 205 13.3.2 Wastewater Treatment 205 13.3.3 Power Supply to Underwater Monitoring Devices 205 13.3.4 Power Supply to Remote Sensors 205 13.3.5 BOD Sensing 205 13.3.6 Hydrogen Manufacture 206 13.4 Microbial Fuel Cells Treatment of Wastewater 206 13.5 Microbial Fuel Cell Design 206 13.6 Construction of MFCs 207 13.6.1 Two Cell MFCs 207 13.6.2 Single Compartment MFCs 208 13.7 MFCs and Wastewater Remediation 208 13.7.1 Microbial Fuel Cells for Wastewater Treatment and Energy Generation 209 13.7.2 Treatment of Sewage and Electricity Production by Microbial Fuel Cells 209 13.7.3 Advanced MFCs for Wastewater Treatment 209 13.8 Wastewater Treatment by MFCs Coupled with Peroxicoagulation Process 210 13.9 MFCs and Generation of Bioelectricity 210 13.10 Electricigens in the MFCs 210 13.11 Future Prospects 210 13.12 Conclusion 211 14 Water Resources Planning and Management Paradigm Decision-Making 214 14.1 Introduction 214 14.2 Freshwater Stress 215 14.3 Globalization 215 14.4 Disparity in Supply and Demand 215 14.5 Planning and Management Approaches 3216 14.5.1 Top-Down Approach 216 14.5.2 Bottom-Up Approach 216 14.6 Integrated Water Resources Management 216 14.7 Water Management and Planning: Goals, Strategies, Decisions, and Scenarios 217 14.8 Systems Approaches to Water Resource System Planning and Decision-Making 218 14.9 Analysis and Implementation Framework 218 14.10 Decision-Making 219 Index 222
Summary: "The remediation of contaminations of aquatic ecosystems is one of the important topics of environmental restoration that is evolving more rapidly. The contamination of water bodies stems primarily from past and present anthropogenic activities and it presently constitutes one of the greatest environmental liabilities for future generations to bear. The significant categories of contaminants usually found in the contaminated sites are halogenated organic compounds, petroleum hydrocarbons, radionuclides, metals and metalloids, pharmaceuticals drugs, microbial toxins and flame retardants. This book provides outstanding about the environmentally safe and economically feasible technologies for treatment of contaminated aquatic ecosystems. The process of remediation of containments from aqua ecosystems involves a phased approach comprising site characterization, risk assessment and remediation technology selection and application. Taking advantage of omic technologies and recent advancement in biotechnology it has become possible to develop novel transgenic plants which are highly efficient in phytoremediation."-- Provided by publisher.
Tags from this library: No tags from this library for this title. Log in to add tags.
    Average rating: 0.0 (0 votes)
Item type Current location Home library Call number Status Date due Barcode Item holds
EBOOK EBOOK COLLEGE LIBRARY
COLLEGE LIBRARY
628.162 B4695 2022 (Browse shelf) Available
Total holds: 0

Includes bibliographical references and index.

Table of Contents

Preface xi

About the Authors xii

1 Emerging Pollutants Remediation Water Systems: Biomass-Based Technologies 1

1.1 Introduction 1

1.2 Adsorption-Based Remediation 3

1.2.1 Biomass 3

1.2.2 Terrestrial and Marine Bioresources 3

1.2.3 Agro-Industrial Wastes 3

1.2.4 Activated Carbons (ACs) 4

1.2.5 Bioresources 4

1.2.6 Agro-Industrial Wastes 4

1.2.7 Activated Sludge (AS) 4

1.3 Bioremediation 4

1.3.1 Phytoremediation 4

1.3.2 Constructed Wetlands (CWs) 5

1.3.3 Microbial Remediation 5

1.3.4 Biocoagulants and Bioflocculants 5

1.4 Multi-Element Water Treatment Process 1

1.4.1 Membrane Bioreactors (MBRs): Biodegradation and Membrane Filtration 6

1.4.2 Activated Carbon and Ozone 7

1.5 Views and Recommendations 7

1.6 Conclusion 7

2 Genetic Engineering for Metal Tolerance and Accumulation 12

2.1 Introduction 12

2.2 Mechanisms of Metal Uptake and their Transport in Plants 14

2.2.1 Heavy Metals Tolerance (Mechanism) in Plants 15

2.2.2 Mechanisms of Avoidance in Plants 15

2.2.3 Binding of Metal to the Cell Wall 16

2.2.4 Mechanisms of Tolerance in Plants 16

2.3 Phytoremediation Using Genetic Engineering Stress-Tolerant Plants 18

2.3.1 Selenium Accumulation by Plants 20

2.3.2 Genetics of Plants Selenium Accumulation 21

2.3.3 Proteins for Metal Accumulation 24

2.4 Genetically Modified Plants Against Uptake, Tolerance and Detoxification of Heavy Metals 24

2.5 Cadmium Tolerance and Accumulation Mechanisms in Plants 26

2.5.1 Immobilization 27

2.5.2 Chelation Using Organic Acids and Amino Acids 27

2.5.3 Stress Peptide Synthesis 27

2.5.4 Cd Transporters 28

2.5.5 Genetic Analysis of Cadmium Tolerance and Accumulation in Plants 28

2.6 Heavy Metal ATPases (HMA) 30

3 Transgenic Approaches for Field Testing and Risk Assessment 42

3.1 Introduction 42

3.2 Transgenic Plants for Environmental Remediation 43

3.3 Degradation Pathways in Plants 44

3.4 Cytochrome P450s for Environmental Perspectives 44

3.5 Transgenic Plants for the Rhizoremediation of Organic Xenobiotics 45

3.6 Transgenic Plants to be Developed for the Phytoremediation of Some Other Priority Pollutants 46

3.7 Potential Genes for Phytoremediation 47

3.8 Hitting Transgenics to the Assessment: Plant Bioremediation 49

3.9 Potential Risks 50

3.9.1 Risk Assessment Theories and Practices 50

3.9.2 Contests Aimed at Multifaceted Risk Valuation 51

3.10 Future Research Guidelines 51

4 Role of RS and GIS in Water Quality Monitoring and Remediation 59

4.1 Introduction 59

4.2 Scope of RS and GIS in Water Monitoring 60

4.3 Assessment of Certain Impurities in Water With the Aid of RS and GIS 61

4.3.1 Suspended Load 61

4.3.2 Phytoplankton 62

4.3.3 Turbidity 62

4.4 Benefits of RS in Assessment of Water Quality 63

4.4.1 Soil Moisture Mapping for Floods and Droughts 63

4.4.2 Spatially Distributed Crop Water Use Estimation 64

4.4.3 Surface Water Quality Monitoring and Remediation 64

4.4.4 Groundwater Quality Monitoring and Remediation 65

4.5 Future Prospectus of RS and GIS Applications in Water Quality Studies 66

5 Advancement on Bioaugmentation: Strategies for Processing Industry Wastewater 71

5.1 Introduction 71

5.2 Present Disposal Techniques and their Limitations 73

5.3 Bioaugmentation as an Emerging Strategy 73

5.3.1 Bioaugmentation Principle 75

5.3.2 Cell Bioaugmentation 75

5.3.3 Biological Augmentation as a Tool for Improving the Wastewater Treatment Efficiency 75

5.3.4 Role of Bioaugmentation in Removing Recalcitrant Pollutants from Industrial Wastewater 76

5.4 Bioaugmentation Applications 76

5.4.1 Removal of Compounds 76

5.4.2 Removal of Lignin 77

5.4.3 Pyridine and Quinoline 77

5.4.4 Cyanides 78

5.4.5 Nicotine 78

5.5 Bioaugmentation Technologies and their Limitations 78

5.5.1 Grazing of Protozoans 79

5.5.2 Inoculum Size 79

5.5.3 Bacteriophage Infection 79

5.6 Strategies for Improving the Effectiveness of Bioaugmentation 80

5.6.1 Immobilizing the Cells in Bioaugmentation 80

5.6.2 Quorum Sensing 80

5.6.3 Gene Transfer and Genetically Modified Microorganisms 81

5.7 Bioaugmentation and Nanotechnology 81

5.8 Future Prospects 82

5.9 Conclusion 82

6 Photocatalysis in Relation to Water Remediation 89

6.1 Introduction 89

6.2 Characteristics of Material 93

6.2.1 Homogeneous Photocatalysis 93

6.2.2 Heterogeneous Photocatalysis 94

6.3 Consequence of Ultra Violet/Titanium Dioxide/Hydrogen Peroxide 95

6.3.1 Chlorophenol 95

6.3.2 2, 4-Dichlorophenol 95

6.3.3 2, 4, 6- Trichlorophenol 96

6.4 Obstacles for Applicability 97

6.4.1 Advancement of Photocatalytic Materials 97

6.4.2 Photocatalytic Reactor Design and System Evaluation 97

6.5 Strategies for Improving Research Outcomes 98

7 Biochemical Systems: Cathode Advanced Wastewater Treatment 103

7.1 Introduction 103

7.2 Cathodic Catalysis in BES and Implications for Catalyst Design 104

7.2.1 Cathodic Catalysis Characteristic in BES 104

7.2.2 Operation Environment 105

7.2.3 Wastewater Electrolyte 105

7.2.4 Cathode Over Potential and Catalysis in BES 106

7.2.5 Photo-Aided Cathodic Catalysis 106

7.3 Wastewater Treatment 107

7.3.1 Highly Biodegradable Wastewater 107

7.3.2 Complex/Low Biodegradable Wastewater 107

7.3.3 Integrated Process for Additional Treatment 108

7.4 Current Bottlenecks and Challenges for BES 108

7.5 Future Directions 111

8 Nanotechnology: Environmental Sustainable Solutions for Wastewater Treatment 116

8.1 Introduction 116

8.2 Water Nanotechnology 118

8.2.1 Adsorption and Separation 118

8.2.2 Catalysis 118

8.2.3 Disinfection 119

8.2.4 Sensing 119

8.2.5 Carbon-Based Nanoadsorbents 119

8.2.6 Metal-Based Nanoadsorbents 120

8.2.7 Polymer-Based Nanoadsorbents 121

8.3 Zeolites 121

8.4 Magnetic Nanocomposites 122

8.5 Nano Zero Valent Iron (nZVI) 122

8.6 Biosorbents 123

8.7 Treatment of Wastewater by Means of Membrane-based Techniques 124

8.8 Nanoparticles for Microbial Control and Disinfection 125

8.9 Antimicrobial Action of Nanoparticles 126

8.10 Potential Applications in Wastewater Treatment 127

8.11 Benefits of Nano-Biotechnology-Based Applications for Water Sustainability 127

8.12 Challenges and Future Outlook 128

9 Biotechnology Intercession in Phytoremediation 138

9.1 Introduction 138

9.2 Genetically Engineered Plants and Phytoremediation 138

9.3 Qualitative Phytoremediators 141

9.4 Biotechnology in Plant Mediated Remediation for Contaminants 141

9.5 Toxic Metals (TMs) 141

9.5.1 Arsenic (As) 142

9.5.2 Mercury (Hg) 143

9.5.3 Organic Pollutants (OPs) 143

9.5.4 Pesticides 144

9.5.5 Oil Spills (OSs) 144

9.6 Conclusion and Future Prospects 145

10 Biofilms in Remediation: Current Trends and Future Perspectives 150

10.1 Introduction 150

10.2 Different Methods for Culturing Biofilms In Vitro 152

10.2.1 Static Microtiter Plate Assays 152

10.2.2 Tube Biofilms 152

10.2.3 Colony Biofilms 152

10.2.4 Biofilm Growth on Peg Lids 153

10.2.5 Rotating Disk and Concentric Cylinder Reactors 153

10.5 Methods for Characterization of Biofilms 154

10.5.1 Confocal Laser Scanning Microscopy (CLSM) 154

10.5.2 Scanning Electron Microscopy (SEM) 155

10.5.3 Atomic Force Microscopy (AFM) 155

10.5.4 Infrared and Raman Spectroscopy 155

10.5.5 X-ray Spectroscopy 155

10.5.6 Nuclear Magnetic Resonance (NMR) Spectroscopy 155

10.6 Biofilm-Based Bioremediation 156

10.7 Nitrogen Fixing Microorganisms in Lakes 158

10.8 Conclusion 159

11 Graphene-Based Absorbents for Wastewater Treatment 164

11.1 Introduction 164

11.2 Graphene-Based Materials 165

11.3 Graphene–Polymer Composites 165

11.4 Applications of Graphene as an Adsorbent in Water Remediation 170

11.4.1 Polycyclic Aromatic Hydrocarbons (PAHs) 171

11.4.2 Phenolic Compounds 172

11.4.3 Pharmaceutical Compounds 173

11.4.4 Pesticides 173

11.4.5 Dyes 174

11.5 Future Scope 175

12 Sewage Sludge: Use in Agriculture Practices 181

12.1 Introduction 181

12.2 Characteristics of Sewage Sludge 18

12.3 Activation of Sewage Sludge 183

12.4 Disposal of Sludge to Land 184

12.5 The Effect of Sludge Application on Soil Properties 185

12.5.1 Physico-Chemical Properties 185

12.5.2 Microbial Parameters of Soil 188

12.5.3 Concentration of Nutrients and the Heavy Metals in Sewage Sludge and Soil 191

12.6 Outlines of Nutrients and Harmful Metals in Sludge and Soil 192

12.7 The Accumulation of Nutrients by Crops 193

12.8 Future Views 194

13 Microbial Fuel Cells for the Treatment of Wastewater 203

13.1 Introduction 203

13.2 Biochemical Sustenance of Microbes 204

13.3 Functioning of MFCs 204

13.3.1 Uses of MFCs 205

13.3.2 Wastewater Treatment 205

13.3.3 Power Supply to Underwater Monitoring Devices 205

13.3.4 Power Supply to Remote Sensors 205

13.3.5 BOD Sensing 205

13.3.6 Hydrogen Manufacture 206

13.4 Microbial Fuel Cells Treatment of Wastewater 206

13.5 Microbial Fuel Cell Design 206

13.6 Construction of MFCs 207

13.6.1 Two Cell MFCs 207

13.6.2 Single Compartment MFCs 208

13.7 MFCs and Wastewater Remediation 208

13.7.1 Microbial Fuel Cells for Wastewater Treatment and Energy Generation 209

13.7.2 Treatment of Sewage and Electricity Production by Microbial Fuel Cells 209

13.7.3 Advanced MFCs for Wastewater Treatment 209

13.8 Wastewater Treatment by MFCs Coupled with Peroxicoagulation Process 210

13.9 MFCs and Generation of Bioelectricity 210

13.10 Electricigens in the MFCs 210

13.11 Future Prospects 210

13.12 Conclusion 211

14 Water Resources Planning and Management Paradigm Decision-Making 214

14.1 Introduction 214

14.2 Freshwater Stress 215

14.3 Globalization 215

14.4 Disparity in Supply and Demand 215

14.5 Planning and Management Approaches 3216

14.5.1 Top-Down Approach 216

14.5.2 Bottom-Up Approach 216

14.6 Integrated Water Resources Management 216

14.7 Water Management and Planning: Goals, Strategies, Decisions, and Scenarios 217

14.8 Systems Approaches to Water Resource System Planning and Decision-Making 218

14.9 Analysis and Implementation Framework 218

14.10 Decision-Making 219

Index 222

"The remediation of contaminations of aquatic ecosystems is one of the important topics of environmental restoration that is evolving more rapidly. The contamination of water bodies stems primarily from past and present anthropogenic activities and it presently constitutes one of the greatest environmental liabilities for future generations to bear. The significant categories of contaminants usually found in the contaminated sites are halogenated organic compounds, petroleum hydrocarbons, radionuclides, metals and metalloids, pharmaceuticals drugs, microbial toxins and flame retardants. This book provides outstanding about the environmentally safe and economically feasible technologies for treatment of contaminated aquatic ecosystems. The process of remediation of containments from aqua ecosystems involves a phased approach comprising site characterization, risk assessment and remediation technology selection and application. Taking advantage of omic technologies and recent advancement in biotechnology it has become possible to develop novel transgenic plants which are highly efficient in phytoremediation."-- Provided by publisher.

Most contamination of water bodies stem from human activity, and the pollution in our water is one of the most important environmental concerns facing future generations. The most significant of these pollutants are halogenated organic compounds, petroleum hydrocarbons, radionuclides, metal and metalloids, pharmaceutical drugs, microbial toxins, and flame retardants. With such a vast array of potential contaminants and dangerously cumulating contamination levels in fragile marine environments, reparative action is more essential than ever.

Aquatic Environmental Bioengineering: Monitoring and Remediation of Contamination provides the reader with a map towards environmentally safe and economically feasible technologies to intervene in polluted aquatic ecosystems. The authors suggest a phased approach consisting of site classification and risk assessment, followed by remediation technology selection and implementation. Effective methods for surveying bodies of water are particularly emphasized, and advancements in the development of novel transgenic plants and microbial fuel cells are put forward as effective tools against environmental contamination and industrial wastewater pollution.

There are no comments for this item.

to post a comment.