Anmerkung: Intro -- HalfTitle -- Series Title -- Title -- Copyright -- Contents -- Chapter 1 Industrial Wastewater and Its Toxic Effects 1 -- 1.1 Introduction -- 1.2 Types of Wastewater -- 1.2.1 Stormwater Runoff Wastewater -- 1.2.2 Domestic Wastewater -- 1.2.3 Agricultural Wastewater -- 1.2.4 Industrial Wastewater -- 1.3 Major Pollutants of Industrial Wastewater -- 1.4 Toxic Effects of Industrial Wastewater -- 1.5 Treatment of Industrial Wastewater -- 1.5.1 Treatment of Wastewater Containing Heavy Metals -- 1.5.2 Treatment of Wastewater Containing Phenolic Compounds -- 1.5.3 Treatment of Wastewater Released from the Paper and Pulp Industry -- 1.5.4 Treatment of Wastewater Released from the Textile Industry -- 1.5.5 Treatment of Hypersaline Effluents -- 1.6 Conclusion -- References -- Chapter 2 Impact of Industrial Wastewater Discharge on the Environment and Human Health 15 -- 2.1 Introduction -- 2.2 General Environmental Pollutants -- 2.2.1 Chemical Pollutants -- 2.2.2 Microbial Pollutants -- 2.3 Ecological Implications and Health Impacts of Industrial Wastewater Discharge on the Environment: Water, Soil and Air -- 2.3.1 Ecotoxicological and Health Effects of PPCP on the Environment -- 2.3.2 Ecotoxicological and Health Effects of Heavy Metals on the Environment -- 2.3.3 Ecotoxicological and Health Effects of Nanoparticles on the Environment -- 2.3.4 Ecotoxicological and Health Effects of Microplastics on the Environment -- 2.4 Ecotoxicological and Health Effects of Bacteria in General, antibiotic‐resistant Bacteria, Parasites and Viruses on the Environment -- 2.5 Challenges and Future Perspectives -- References -- Chapter 3 Detrimental Effects of Industrial Wastewater on the Environment and Health 40 -- 3.1 Introduction -- 3.2 Toxic Effect of Heavy Metals -- 3.3 Toxic Effect of Antibiotics -- 3.4 Toxic Effect of Pesticides. , 3.5 Toxic Effect of Microplastics -- 3.6 Conclusion -- References -- Chapter 4 Treatment and Management Strategies for Industrial Wastewater 53 -- 4.1 Introduction -- 4.2 Wastewater From Industries, Its Characterization and Impacts -- 4.2.1 Pulp and Paper Industry -- 4.2.2 Textile Industry -- 4.2.3 Petrochemical Industries -- 4.2.4 Iron and Steel Industries -- 4.3 Laws and Regulations for Industrial Wastewater Treatment -- 4.4 Conventional Methods for Industrial Wastewater Treatment -- 4.4.1 Coagulation or Flocculation -- 4.4.2 Ion Exchange -- 4.4.3 Membrane Filtration -- 4.4.4 Advanced Oxidation Processes -- 4.5 Biological Methods for Industrial Wastewater Treatment -- 4.5.1 Aerobic Process -- 4.5.2 Anaerobic Process -- 4.6 Management Strategies for Industrial Wastewater Treatment -- 4.7 Conclusion -- References -- Chapter 5 Introduction to Industrial Wastewater and Allied Treatment Technologies 74 -- 5.1 Introduction -- 5.2 Sources of Industrial Wastewater -- 5.3 Treatment of Industrial Wastewater -- 5.3.1 Conventional Methods -- 5.3.2 Advanced Bioprocesses -- 5.4 Challenges in Watewater Treatments -- References -- Chapter 6 Bioreactors: A Biological and Bioengineering Prodigy 87 -- 6.1 Introduction -- 6.2 Understanding Bioreactors -- 6.3 Various Features and Types of Bioreactor -- 6.4 Modelling of a Bioreactor -- 6.4.1 Basic Modelling -- 6.4.2 Validation -- 6.4.3 Hybrid Models -- 6.4.4 Balance Regions -- 6.4.5 Bioreactor Fluid Dynamics -- 6.4.6 Bioreactor Operation -- 6.5 Scale-down and -up of a Bioreactor -- 6.5.1 Scale-down Phases 1, 2 and 3 -- 6.5.2 Scale-up -- 6.6 Recent Trends in the Application of Various Types of Bioreactor -- 6.7 Limitations and Future Prospects -- 6.8 Conclusion -- References -- Chapter 7 Challenges in Industrial Wastewater Treatment Using Biological Reactors 105 -- 7.1 Introduction. , 7.2 Industrial Wastewater Composition and Treatability -- 7.3 Biological Processes for Industrial Wastewater Treatment -- 7.3.1 Aerobic Biodegradation -- 7.3.2 Anaerobic Biodegradation -- 7.4 Advanced Biological Wastewater Treatment Technology -- 7.4.1 Membrane Bioreactors (MBRs) -- 7.4.2 Moving-bed Biofilm Reactor (MBBR) -- 7.4.3 Granular Sludge Technology (GST) -- 7.5 Challenges in Industrial Wastewater Treatment Using Biological Processes -- 7.5.1 Agrochemical Wastewater -- 7.5.2 Coal Gasification Wastewater -- 7.5.3 Dairy Wastewater -- 7.5.4 Electroplating Wastewater -- 7.5.5 Mustard Tuber Wastewater -- 7.5.6 Palm Oil Mill Wastewater -- 7.5.7 Pharmaceutical Wastewater -- 7.6 Summary -- References -- Chapter 8 Challenges in Designing and Operation of a Bioreactor for Treatment of Wastewater 131 -- 8.1 Introduction -- 8.2 Basics of a Bioreactor -- 8.2.1 Mode of Operation -- 8.2.2 Types of Bioreactor -- 8.3 Role of Bioreactors in Wastewater Treatment -- 8.3.1 Comparison of Conventional an Activated Sludge Processes and an MBR -- 8.4 Conceptual Design and Approaches for Bioreactor Design -- 8.4.1 Energy Recovery in MBRs -- 8.4.2 Treated Wastewaters from Membrane Bioreactors -- 8.4.3 Operating Conditions and Performance of Membrane Bioreactors -- 8.4.4 Membrane Materials and Modules Used in Membrane Bioreactors -- 8.4.5 Fluxes and Membrane Area of Membrane Bioreactors -- 8.4.6 Membrane Design -- 8.4.7 Design of an Aeration System -- 8.4.8 Cost Benefit Analysis -- 8.5 Challenges Associated with Design and Operation -- 8.5.1 Membrane Fouling -- 8.6 Fouling Control Strategies -- 8.6.1 Pretreatment of Feed Wastewater -- 8.6.2 Physical Cleaning and Backwashing -- 8.6.3 Cleaning -- 8.6.4 Membrane Surface Modification -- 8.6.5 Optimization and Enhancement of Aeration -- 8.6.6 Biological Control Techniques -- 8.7 Reuse and Recovery of Wastewater Using an MBR. , 8.8 Conclusion -- References -- Chapter 9 Different Types of Advanced Bioreactors for the Treatment of Industrial Effluents 157 -- 9.1 Introduction -- 9.1.1 Conventional Biological Treatments and Their Limitations -- 9.1.2 Advanced Bioprocesses and Available Reactor Designs -- 9.1.3 Aim and Objectives of the Chapter -- 9.2 Sequencing Batch Reactor for Effluent Treatment -- 9.3 Aerobic and Anaerobic Stirred-tank Bioreactors -- 9.4 Fixed- and Fluidized- Bed Bioreactor Designs -- 9.5 Membrane-based Technology and Other Possible Integration Approaches -- 9.6 Conclusions and Future Perspectives -- References -- Chapter 10 Membrane Bioreactors: An Advanced Technology to Treat Industrial Waste Water 174 -- 10.1 Introduction -- 10.2 Conventional Techniques for the Treatment of Industrial Waste Water -- 10.3 Advance Technologies for the Treatment of Industrial Waste Water -- 10.3.1 Advanced Oxidation Process (AOP) -- 10.3.2 UV Irradiation -- 10.3.3 Automatic Variable Filtration -- 10.3.4 Electrochemical Processes -- 10.3.5 Adsorption -- 10.3.6 Membrane Filtration -- 10.4 Membrane Bioreactor -- 10.4.1 Working Principles of MBRs -- 10.4.2 Choice of Membranes and Membrane Elements for MBRs -- 10.4.3 Types of MBR -- 10.4.4 Membrane Fouling and Its Control in an MBR -- 10.4.5 MBR vs CAS -- 10.4.6 Application of MBRs -- 10.5 Conclusion and Future Prospects -- References -- Chapter 11 Membrane Bioreactors for Industrial Wastewater Treatment 215 -- 11.1 Introduction -- 11.2 Basics of a Membrane Bioreactor -- 11.3 Limitations and Trouble-shooting of MBR Operation -- 11.4 Commercial MBR Plants and MBR Application in Industrial Sectors -- 11.5 Industrial Application of Membrane Bioreactors -- 11.5.1 Application of the Membrane Bioreactor in Food and Beverage Industries -- 11.5.2 Application of the Membrane Bioreactors in Pharmaceutical Industries. , 11.5.3 Application of the Membrane Bioreactor in Petrochemical Industries -- 11.5.4 Application of the Membrane Bioreactor in Textile Industries -- 11.5.5 Application of the Membrane Bioreactor in Paper-pulp and Tannery Industry -- 11.6 Future Prospects for Membrane Bioreactor Technology -- References -- Chapter 12 Investigation and Treatment of Industrial Wastewater by Membrane Bioreactors: An Innovative Approach 241 -- 12.1 Introduction -- 12.2 Process Description and Configuration of MBR -- 12.3 Effect of MBR on Microorganism and Pollutants and Reuse Options -- 12.4 The Quality of the Effluent Water after MBR Treatment -- 12.5 The Cost Associated with MBRs -- 12.6 Limitations and Advantages of Membrane Bioreactors -- 12.7 Advancement in MBR Technology -- 12.8 Conclusion -- References -- Chapter 13 Membrane Bioreactors for Separation of Persistent Organic Pollutants From Industrial Effluents 257 -- 13.1 Introduction -- 13.2 Sources and Toxicity of POPs -- 13.2.1 Occurrence of Micro-pollutants in Groundwater and Drinking Water -- 13.2.2 Impact of Micro-pollutants on the Environment -- 13.2.3 Toxicity Induced by Micro-pollutants -- 13.3 MBRs for Efficient Treatment of POPs -- 13.4 Major Processes of Pollutant Removal Occurring in MBRs -- 13.4.1 Sorption -- 13.4.2 Biodegradation -- 13.4.3 Stripping/Volatilization -- 13.5 Factors Affecting MBR Efficiency -- 13.5.1 Physicochemical Properties of POPs -- 13.5.2 Operating Conditions -- 13.6 Integrated MBR-based Processes -- 13.6.1 AOPs-MBR -- 13.6.2 Reverse Osmosis and Forward Osmosis Membrane Systems -- 13.6.3 Granular MBR -- 13.6.4 Membrane Distillation Bioreactor (MDBR) -- 13.6.5 Biofilm/Bio-entrapped Membrane Bioreactor -- 13.7 Membrane-based Separation of Treated Water from Mixed Liquor -- 13.7.1 Ultrafiltration Membranes -- 13.7.2 Nanofiltration Membranes. , 13.8 Different Tools for Process Optimization.

Anmerkung: Front Cover -- Fungi Bio-Prospects in Sustainable Agriculture, Environment and Nano-Technology: Volume 1: Fungal Diversity of Sustainable Agriculture -- Copyright Page -- Contents -- List of Contributors -- Preface -- 1 Endophytic fungi: A review of survival strategies that influence the biodiversity studies associated with biopotential pr... -- Introduction -- Importance to study the endophytic fungal diversity -- Fungal endophytes from subtropics and tropical regions -- Endophytes will be modern microbial technology to fulfill our societal needs -- Significance on understanding the modern era challenges -- Conclusion -- Acknowledgments -- References -- 2 Evaluation of phylloplane fungal flora and host plants in the Southern Western Ghats -- Scope of the study -- References -- 3 Fungal endophytes from seaweeds and bio-potential applications in agriculture -- Introduction -- Seaweeds -- Endophytic fungi -- Diversity of molecules produced by seaweed endophytic fungi -- Role of endophytic fungi in plant growth -- Seaweed endophytic fungi as phosphate solubilizers -- Seaweed endophytic fungi as potassium solubilizers -- Bioactive compounds -- Future perspectives -- Acknowledgments -- References -- 4 Fungal endophytes: Entry, establishment, diversity, future prospects in agriculture -- Introduction -- What are endophytes? -- How do these endophytes enter and establish inside the plants? -- How diverse these endophytes are? -- How these fungal endophytes can contribute to sustainable agriculture? -- Phosphate solubilization -- Conclusion -- References -- 5 Fungal endophytes, biodiversity and biopotential applications -- Introduction -- History and evolution of endophytic fungi -- Endophytic fungi -- Biodiversity of fungal endophytes in India -- Unique features of marine environment and their relevance to marine fungi -- Classification of endophytes. , Sponge associated fungal endophytes -- Bioactive compounds and their biopotential applications -- Primary and secondary metabolites -- Factors affecting the production of metabolites -- Future prospects -- References -- 6 The role of fungi in abiotic stress tolerance of plants -- Introduction -- Fungal symbiosis -- Types of fungal symbionts -- Role of fungus in various abiotic stress tolerance -- Salinity stress -- Endophytes -- Mycorrhiza -- Drought stress -- Endophyte -- Mycorrhiza -- Heavy metal stress -- Endophyte -- Mycorrhiza -- Temperature (heat and cold stress) -- Endophyte -- Mycorrhiza -- Conclusion -- References -- 7 Phytopathogenic fungi and their biocontrol applications -- Introduction -- Plant pathology -- Definition of plant pathology -- Plant pathologist -- Definition of disease -- The disease triangle -- Factors affecting disease development -- Pathogen factors -- Introduction of new pathogen -- Presence of aggressive strain of the pathogen -- High birth rate of the pathogen -- Low death rate -- Easy and rapid dispersal of the pathogen -- Adaptability of the pathogen -- Host factors -- Susceptibility of the host -- Aggregation and distribution of susceptible hosts -- Introduction of new host(s) -- Introduction of new collateral or alternate hosts -- Environmental factors -- Simple interest diseases -- Compound interest diseases -- The edaphic environment -- Interactions among factors -- Plant pathogens -- Classification of plant disease -- Fungi -- Phenomenon of infection - pre-penetration, penetration and post penetration -- Pre entry (pre-penetration) -- Entry (penetration) -- Colonization (post penetration) -- Pathogenesis - role of enzymes, toxins, growth regulators and polysaccharides -- Enzymes -- Cellulases -- Hemicellulases -- Ligninases -- Toxins as chemical weapons of pathogens -- Tabtoxin -- Phaseolotoxin -- Tentoxin. , Host-specific toxins -- T-toxin -- HC-toxin -- Growth regulators as weapons -- Auxins -- Gibberellins -- Ethylene -- General principles of plant diseases management - importance, general principles: avoidance, exclusion, eradication, protec... -- Biocontrol of plant disease -- Interactions between plants and beneficial microbes -- Biological control and PGPR -- Parasitism and lysis -- Antibiosis -- Competition -- Trichoderma viride -- Bacillus subtilis -- Pseudomonas fluorescens -- Plant products and antiviral principles in plant disease management -- Neem products -- Neem seed Kernel extract (NSKE) -- Neem oil solution -- Neem cake extract -- Neem cake -- Other plant products -- PGPR -- Disease control -- Ways that PGPR promote plant growth -- Anti-viral principle (AVP) -- Biotechnological developments -- Disease management by biotechnological methods -- Genetic engineering -- Vectors for transfer of genes -- DNA construction -- Coat-protein expression in transgenic plants -- Satellite RNA expression in transgenic plants -- MIC RNA expression in transgenic plants -- Use of RFLP markers for cloning resistance genes -- Disease resistance genes mapped using RFLP markers detoxification of pathotoxin -- Activation of plant defense mechanism - phytoalexins -- Defense related genes -- a. Single gene defense mechanism -- Chitinases and glucanases -- b. Multigenic defense mechanism -- Peroxidases -- Activation of defense genes by chemicals -- Cell and tissue culture -- Somaclonal variation -- Disease resistant plants from tissue culture -- Anther culture -- Protoplasmic fusion -- Reference -- 8 Impact of fungal inoculants on sustainable agriculture -- Introduction -- Soil and soil organisms and nutrients -- Use of microbes -- Microbial inoculants -- Fungal inoculants -- Future prospects and limitations -- Conclusion -- References -- Further reading. , 9 Arbuscular mycorrhizal (AM) fungi: Potential role in sustainable agriculture -- Introduction -- Role of AMF for improving agricultural yield and quality -- Role of AMF in biotic stress management -- Viral diseases -- Nematodes -- Role of AMF against abiotic stress management -- Drought stress -- Salinity stress -- Heavy metal stress -- AMF mediated defense mechanisms -- Factors affecting AMF potential -- Commercial potential of AMF -- Future challenges and strategies in AMF mediated disease management -- Conclusion -- Acknowledgement -- References -- 10 Endophytic fungal diversity of selected medicinal plants and their bio-potential applications -- Diversity of fungal endophytes -- The plant -- Tinospora cordifolia (Willd.) Miers ex Hook F & -- Thoms -- Systematic position -- Adhatoda vasica Nees -- Systematic position -- Murraya koenigii (L.) Spreng -- Systematic position -- Endophytes in laboratory culture -- Gateway of fungi in host plant -- Histological studies -- Isolation and identification of endophytic fungi -- Metabolites from endophytic fungi -- Biological roles of fungal endophytes -- Nutrient pedaling and phyto-stimulation -- Anticancer activity -- Antimicrobial properties -- Antidiabetic activity -- Immunosuppressive activity -- Antiviral activity -- Conclusion -- References -- Further reading -- 11 Prospect of biofuel production by fungus -- Introduction -- Bioethanol production -- Status of bioethanol production in the world and in India -- Feedstocks and biomass used for bioethanol production -- Fungus as microorganism for pretreatment of lignocellulosic substrates for bioethanol production -- Bioreactors for bioethanol production by fungus -- Biodiesel production -- Status of biodiesel production in the world and in India -- Feedstocks and biomass used for biodiesel production -- Fungus as microorganism for oil production. , Production of biodiesel from fungal oil after transesterification process -- Nano catalyzed biodiesel production -- Alumina based catalysts -- Silica-based catalysts -- Calcium oxide-based catalysts -- Zirconia based catalysts -- Magnesium oxide-based catalysts -- Titanium dioxide-based catalysts -- Heteropolyacid based catalysts -- Carbon-based catalysts -- Biogas production -- Status of biogas production in the world and in India -- Feedstocks and biomass used for biogas production -- Production of biogas by anaerobic digestion of organic feedstocks by microorganisms -- Fungus as microorganism for anaerobic digestion -- Microbial fuel cell -- Current scenario of MFC's in the world and in India -- Mechanism of electricity production in MFC -- Mechanisms of electron transfer in MFC -- Direct electron transfer -- Indirect electron transfer (exogenous or endogenous) -- Why fungus is superior to bacteria or algae? -- Fungus as anode and cathode -- Fungi/yeasts as biocatalyst in cathode -- Fungi/yeasts as biocatalyst in anode -- Applications of MFC -- Production of bio electricity -- Biohydrogen production -- Waste water treatment containing organic matter and heavy metals -- Carbon sequestration -- Biosensor -- Conclusions -- Acknowledgement -- References -- 12 Fungal endophytes and their applications as growth promoters and biological control agents -- Introduction -- Plant-endophyte interaction -- Fungal endophytes and their plant host -- Importance/functional significance of fungal endophytes -- Role of fungal endophytes in plant growth promotion -- Mode of action for growth promotion -- Fungal endophytes as biocontrol agents -- Mechanism for biocontrol activities -- Synthesis of bioactive compounds -- Conclusion -- References -- 13 Rhizosphere fungi and their plant association: Current and future prospects -- Introduction. , Plant-microbe communication.

Anmerkung: Front cover -- Half title -- Full title -- Copyright -- Contents -- Contributors -- 1 - Nanoadsorbents for scavenging emerging contaminants from wastewater -- 1.1 Introduction -- 1.2 Emerging contaminants -- 1.3 Occurrence of emerging contaminants in aquatic systems -- 1.4 Exposure pathways of emerging contaminants in the environment -- 1.5 Treatment technologies for removal of ECs -- 1.6 Conventional treatment methods -- 1.7 Emerging methods -- 1.7.1 Biological treatment method -- 1.7.2 Advanced oxidation process -- 1.8 Nanoadsorbents -- 1.9 Classification of nanoadsorbents -- 1.10 Methods for preparation of nanoadsorbents -- 1.11 Properties of nanoadsorbents -- 1.12 Mechanisms of nanoadsorption -- 1.13 The π-π interaction -- 1.14 Electrostatic interaction -- 1.15 Hydrophobic interaction -- 1.16 Hydrogen bonding -- 1.17 Factors affecting adsorption process -- 1.17.1 pH -- 1.17.2 Ionic strength -- 1.17.3 Dissolved organic matter -- 1.18 Conclusions -- References -- 2 - Treatment aspect of an emerging pollutant from Pharmaceutical industries using advanced oxidation process: past, curre ... -- 2.1 Introduction -- 2.2 Treatment technologies -- 2.2.1 Recovery process -- 2.2.2 Phase changing technologies -- 2.2.2.1 Adsorption -- 2.2.2.2 Membrane technology -- 2.2.3 Biological process -- 2.3 Advanced oxidation process -- 2.3.1 Nonphotochemical methods -- 2.3.1.1 Ozonation -- 2.3.1.2 Ozone and hydrogen peroxide (Peroxone) -- 2.3.2 Catalytic ozonation -- 2.3.3 Fenton system -- 2.3.3.1 Sulfate-based AOPs -- 2.3.4 Photochemical methods -- 2.3.4.1 O 3  + UV Method -- 2.3.4.2 H 2 O 2 +UV light Method -- 2.3.4.3 H 2 O 2 +UV+ O 3 Method -- 2.3.4.4 Photolysis -- 2.3.4.5 UV/persulfate -- 2.3.4.6 Photo-Fenton Method -- 2.3.4.7 Photocatalysis -- 2.3.4.8 Other AOPs -- 2.4 Future prospects -- References. , 3 - Membrane bioreactor (MBR) as an advanced wastewater treatment technology for removal of synthetic microplastics -- 3.1 Introduction -- 3.2 Microplastic generation and pollution -- 3.3 Effect of Synthetic microplastic pollution -- 3.4 Technical implementation of membrane bioreactor (MBR) for elimination micro plastic pollutants -- References -- 4 - Strategies to cope with the emerging waste water contaminants through adsorption regimes -- 4.1 Introduction -- 4.2 Uptake of pollutants from water via adsorption -- 4.3 Adsorbents and there use in purification of waters -- 4.4 Various emerging pollutants and their effects -- 4.4.1 Heavy metals -- 4.4.2 Dyes -- 4.4.3 Pharmaceuticals -- 4.4.4 Fluoride -- 4.4.5 Arsenic -- 4.4.6 Other emerging pollutants -- 4.5 Adsorption strategies for removal of emerging pollutants from waste waters -- 4.6 Adsorption of pollutants using hydrothermal carbonization: an environment safe procedure using carbon adsorbents -- 4.7 Use of hydrothermal carbonization (HTC) in adsorption -- 4.7.1 Dye adsorption -- 4.7.2 Pesticide(s) adsorption -- 4.7.3 Antibiotics/drugs adsorption -- 4.7.4 Endocrine disrupting chemicals (EDC) -- 4.8 Metals and metal ions adsorption by HTCs -- 4.9 Adsorption of metal(s) from mixture of metals -- 4.10 Adsorption of heavy metals using HTCs -- 4.11 Use of cost-effective adsorbent for adsorption of heavy metals -- 4.12 Uptake of metals using low-cost adsorbent materials -- 4.13 Use of agricultural residues as adsorbents -- 4.14 Uses of industrial wastes as adsorbents -- 4.14.1 Marine materials -- 4.14.2 Clay and zeolite -- 4.15 Adsorption/biosorption of antibiotics from waste water -- 4.16 Elimination of heavy metals via adsorption/biosorption -- 4.17 Heavy metals uptake using activated sludge and sludge-derived materials. , 4.18 Uptake of endocrine disrupting chemicals (EDC) -- 4.19 Future prospects -- 4.20 Conclusion -- References -- 5 - Performances of membrane bioreactor technology for treating domestic wastewater operated at different sludge retention ... -- 5.1 Introduction -- 5.1.1 Fundamentals of membrane bioreactors -- 5.1.2 Development of MBR studies -- 5.1.3 Membrane fouling in MBR systems -- 5.1.4 Performances of MBRs at high biomass retention -- 5.1.5 Task and purpose of the study -- 5.2 Materials and methods -- 5.2.1 Experimental setup -- 5.2.2 Sludge retention time -- 5.2.3 Analysis methods -- 5.3 Results and discussion -- 5.3.1 Effect of SRTs on sludge concentration in the system -- 5.3.2 Effects of SRT on sludge bioactivity -- 5.3.3 Effect of SRT on SVI and viscosity -- 5.3.4 Effects of SRT on COD removal in the system -- 5.4 Influence of SRT on sludge particle size distribution -- 5.5 Conclusions -- Acknowledgements -- Abbreviations -- References -- 6 - Advances in nanotechnologies of waste water treatment: strategies and emerging opportunities -- 6.1 Introduction -- 6.2 Metallic nanoparticles -- 6.3 Nanoadsorbents -- 6.4 Nanobiosorbents -- 6.5 Nanomembranes -- 6.6 Nanocatalysts -- 6.6.1 Photocatalyst based advance oxidation process -- 6.7 Conclusions -- Acknowledgements -- References -- 7 - Water and Wastewater Treatment through Ozone-based technologies -- 7.1 Introduction -- 7.2 Global water scenario -- 7.3 Strategies for solving the water shortage issues -- 7.4 Why ozone-based technologies used for water and wastewater treatment? -- 7.4.1 Advanced Oxidation Process (AOP) -- 7.4.2 Benefits of ozone (O 3 ) based treatment -- 7.5 Worldwide status, history, and background of O 3 based technology for drinking water and wastewater treatment -- 7.6 Use of ozone-based technology for disinfection. , 7.6.1 Mechanisms of Inactivation by Ozone -- 7.7 Treatment of municipal and industrial wastewater through Ozone-based technology -- 7.8 Removal of physical pollutants (odor and taste) through Ozone-based technologies -- 7.9 Removal of various chemical pollutants (COD, BOD and coloring agents) from wastewater through Ozone-based technologies -- 7.10 Factors affecting the Ozonation process -- 7.11 Conclusion and Future prospects -- References -- 8 - Constructed wetland: a promising technology for the treatment of hazardous textile dyes and effluent -- 8.1 Introduction -- 8.2 Classification of dyes -- 8.3 Impact of dye toxicity on environment -- 8.4 Impact of dye toxicity on living beings -- 8.5 Dye remediation strategies -- 8.5.1 Physical methods -- 8.5.2 Chemical methods -- 8.5.3 Biological methods -- 8.6 Constructed wetlands: a step towards technology transfer -- 8.7 Classification of constructed wetlands -- 8.8 Recent developments in textile wastewater treatments using constructed wetlands -- 8.9 Conclusion and future prospective -- References -- 9 - Biogenic nanomaterials: Synthesis, characteristics, and recent trends in combating hazardous pollutants (An arising sc ... -- 9.1 Introduction -- 9.2 History of nanotechnology and conventional synthetic routes of nanomaterials -- 9.3 Nanobiotechnology: An arising scientific horizon -- 9.3.1 Biologically fabricated NPs for the removal of hazardous water pollutants -- 9.3.1.1 Biologically fabricated NPs using bacteria and actinomycetes -- 9.3.1.2 Biologically fabricated NPs using fungi -- 9.3.1.3 Biologically fabricated NPs using yeast -- 9.3.1.4 Biologically fabricated NPs using algae -- 9.3.1.5 Biologically fabricated NPs using plant extracts -- 9.3.1.6 Biologically fabricated NPs using agro-industrial waste extracts. , 9.3.2 Possible mechanisms involved in biomimetic synthesis of NPs -- 9.3.2.1 Role of enzymes and proteins -- 9.3.2.2 Role of exopolysaccharides -- 9.4 Advantages, limitations, drawbacks, and future perspectives of nanobiotechnology -- 9.5 Conclusions -- References -- 10 - Removal of emerging contaminants from pharmaceutical wastewater through application of bionanotechnology -- 10.1 Introduction -- 10.2 Overview of contaminants in pharmaceutical wastewater -- 10.3 Applications of nanomaterials for the removal of pharmaceutical contaminants -- 10.3.1 Nanofiltration -- 10.3.2 Advanced oxidation process -- 10.3.3 Nanosorbents (nanotubes and zeolites) -- 10.4 Concluding remarks -- References -- 11 - Recent advances in pesticides removal using agroindustry based biochar -- 11.1 Introduction -- 11.2 What is biochar? -- 11.3 Characteristics of biochar -- 11.3.1 Porosity and surface area -- 11.3.2 pH -- 11.3.3 Functional groups at the surface -- 11.3.4 Carbon content and aromatic structures -- 11.3.5 Mineral composition -- 11.4 Modified biochar -- 11.5 Hazards of pesticides to environment and health -- 11.6 Recent development in pesticides sorption on biochar -- 11.6.1 Herbicides sorption -- 11.6.2 Insecticides sorption -- 11.6.3 Fungicides sorption -- 11.6.4 Nematicides sorption -- 11.7 Conclusion and future perspective -- References -- 12 - Bioremediation - the natural solution -- 12.1 Introduction -- 12.2 Characteristics of municipal wastewater -- 12.2.1 Organic impurities -- 12.2.2 Solids -- 12.2.3 Nutrients -- 12.2.3.1 Phosphorus -- 12.2.3.2 Nitrogen -- 12.2.3.3 Nitrogen present in municipal wastewater treatment plants (WWTPS) -- 12.2.4 Effects of phosphorus and nitrogen on environment -- 12.2.5 Pathogens -- 12.3 Wastewater treatment -- 12.3.1 Physical treatment -- 12.3.2 Chemical treatment. , 12.3.3 Thermal treatment.