Preface xvii 1 Green Sustainability, Nanotechnology and Advanced Materials - A Critical Overview and a Vision for the Future 1 Sukanchan Palit and Chaudhery Mustansar Hussain 1.1 Introduction 2 1.2 The Aim and Objective of This Study 2 1.3 The Need and the Rationale of This Study 3 1.4 Environmental and Green Sustainability 3 1.5 The Scientific Doctrine of Green Sustainability and Green Engineering 4 1.6 Scientific Vision and Scientific Doctrine of Nanotechnology 5 1.7 What Do You Mean by Advanced Materials? 5 1.

8 The World of Advanced Materials Today 6 1.9 Recent Scientific Endeavour in the Field of Green Sustainability 6 1.10 The Challenges and Vision of Research Pursuit in Nanotechnology Today 10 1.11 Technological Vision and the Scientific Endeavour in Advanced Materials 11 1.12 The Vision of Energy and Environmental Sustainability 12 1.13 Global Water Shortage and the Challenges of Research and Development Initiatives 13 1.14 Heavy Metal and Arsenic Groundwater Remediation 14 1.15 Water Purification Technologies and the World of Environmental Sustainability 15 1.

16 Future Frontiers and Future Flow of Scientific Thoughts 16 1.17 Future Research Trends in Sustainability and Nanotechnology Applications 16 1.18 Summary, Conclusion and Scientific Perspectives 17 References 17 2 Valorization of Green and Sustainable Advanced Materials from a Biomed Perspective - Potential Applications 19 Muhammad Bilal, Tahir Rasheed, Abaid Ullah and Hafiz M. N. Iqbal 2.1 Introduction 20 2.2 Multi-Functional Characteristics of Green and Sustainable Materials - Smart Polymers 20 2.3 Biomedical Potentialities of Biopolymers and/or Biopolymers-Based Constructs 24 2.

4 Mesoporous Silica Nanoparticles - Biomedical Applications 25 2.5 BioMOFs: Metal-Organic Frameworks 28 2.6 Bioinspired MOFs - Biomedical Application and Prospects 29 2.7 Drug Delivery Perspectives of MOFs 31 2.8 MOF in Enantioseparation of Drug Racemates 31 2.9 Porous Covalent Organic Cages as Bio-Inspired Materials 33 2.10 pH-Responsive Hydrogels for Drug Delivery Applications 34 2.11 Concluding Remarks 35 Conflict of Interest 38 Acknowledgements 38 References 38 3 Applications of Textile Materials Using Emerging Sources and Technology: A New Perspective 49 Pintu Pandit, Saptarshi Maiti, Gayatri T.

N. and Aranya Mallick 3.1 Introduction 50 3.2 Synthesis, Forms, Properties and Applications of Graphene 52 3.2.1 Structure and Forms of Graphene 52 3.2.2 Synthesis and Production Methods of Graphene 53 3.

2.3 Properties of Graphene 54 3.2.4 Applications of Graphene 55 3.2.4.1 Application of Graphene in Energy Storage, Optoelectronics, and Photovoltaic Cell 55 3.2.

4.2 Application of Graphene in Ultrafiltration and Bioengineering 57 3.2.4.3 Application of Graphene in Textile Materials and Composites 57 3.3 Essential Role for Nanomaterials in Textiles 59 3.3.1 Developing and Processing Nanoengineered Textiles 60 3.

3.2 Nanofiber Application Driven by Function-of-Form Paradigm 63 3.4 Types, Synthesis and Application of Dendrimers 65 3.4.1 Types of Dendrimers 66 3.4.2 Synthesis of Dendrimers (Divergent and Convergent Method) 67 3.4.

3 Application of Dendrimers in Chemical Processing of Textile Materials 68 3.4.4 Application of Dendrimers in Medical Textiles 69 3.4.5 Application of Dendrimers in Effluent Treatment 70 3.5 Application of Plasma Technology in Textile Materials 71 3.6 Synthesis and Applications of Biopolymer-Based Absorbents 74 3.7 Conclusion 77 References 78 4 Nanotechnology and Nanomaterials: Applications and Environmental Issues 85 Pooja Thakur, Kamal Kumar Bhardwaj and Reena Gupta 4.

1 Introduction 86 4.2 NPs and Nanodevices 87 4.3 Types of NPs 88 4.3.1 Carbon Based NPs 89 4.3.1.1 Fullerenes 89 4.

3.1.2 Carbon Nanotubes 90 4.3.1.3 Graphene Nanofoils 90 4.3.1.

4 Carbon Nanofibres 91 4.3.1.5 Carbon Black 91 4.3.1.6 Carbon Nanofoams 92 4.3.

2 Inorganic NPs 92 4.3.2.1 Metals 92 4.3.2.2 Metal Oxides 92 4.3.

2.3 Quantum Dots 93 4.3.3 Organic NPs 94 4.3.3.1 Organic Polymers 94 4.3.

3.2 Biologically Inspired NPs 94 4.4 Applications of NPs 94 4.4.1 Applications of Nanotechnology by Sectors of Activity 94 4.4.2 Nanotechnology Applications by NP Type 95 4.5 Environmental Impacts of Nanotechnology and its Products 95 4.

5.1 Potential Environmental Effects 100 4.5.2 Fate of NPs in the Environment 101 4.5.3 Positive Effects on Environment 104 4.5.4 Negative Effects on Environment 105 4.

6 Conclusion 106 Acknowledgements 106 Conflict of Interests 107 References 107 5 Chitosan in Water Purification Technology 111 Ajith James Jose, Ann Mary Jacob, Manjusha K. C. and Jincymol Kappen 5.1 Introduction 111 5.2 Chitosan 112 5.3 Chitosan in Waste Water Treatment 115 5.3.1 Treatment of Agricultural Waste Water 115 5.

3.2 Treatment of Textile Effluents 116 5.3.3 Household Drinking Water Treatment 117 5.4 Mechanism Behind the Waste Water Treatment by Chitosan 118 5.4.1 Removal of Heavy Metals 118 5.4.

2 Removal of Bacteria 120 5.5 Conclusion 121 References 121 6 Green and Sustainable Advanced Materials - Environmental Applications 125 Swapnil Sharma, Vivek Dave, Kanika Verma and Jaya Dwivedi 6.1 Introduction 125 6.2 Application of Advanced Green Sustainable Materials in Sensing and Removal of Water Toxicants 126 6.2.1 Materials Used for Sensing and Removal of Dyes and Heavy Metals from Water 126 6.2.1.

1 Dyes 126 6.2.1.2 Heavy Metal 127 6.2.1.3 Removal of Heavy Metal and Dye from Naturally Derived Bio-Sorbents 134 6.2.

2 Removal of Microbial Pathogen from Water 137 6.2.3 Removal of Radioactive Pollutants from Water 146 6.3 Removal of Contaminants from Air 147 6.4 Application of Sustainable Material in Soil Remediation 148 Acknowledgement 149 References 149 7 Green and Sustainable Copper-Based Nanomaterials - An Environmental Perspective 159 Santosh Bahadur Singh 7.1 Introduction 160 7.2 Copper-Based Nanomaterials and its Sustainability 162 7.2.

1 Metallic Copper Nanoparticles (Cu-NPs) 162 7.2.2 Copper Oxide (CuO)-Based NPs 163 7.2.3 Supported Copper Nanomaterials 164 7.2.4 Growth Mechanism of Copper Nanomaterials 165 7.3 Copper-Based Nanomaterials in Catalysis: As a Tool for Environmental Cleaning 165 7.

4 Copper-Based Nanomaterials in Environmental Remediation 166 7.5 Environmental Perspective of Copper Nanomaterials 169 7.6 Concluding Remarks 170 References 170 8 An Excellence Method on Starch-Based Materials: A Promising Stage for Environmental Application 177 Tanvir Arfin and Kamini Sonawane 8.1 History 177 8.2 Sources 178 8.2.1 Tubers or Roots 178 8.2.

2 Corn 178 8.3 Physiochemical Properties 178 8.3.1 Characteristics of Starch Granules 178 8.3.2 Glass Transition Temperature and Birefringence 180 8.3.3 Solubility and Swelling Capacity 181 8.

3.4 Retrogradation and Gelatinization 181 8.3.5 Thermal and Rheological Properties 181 8.4 Starch Gelatinization Measurement 182 8.5 Processing of Starch 182 8.5.1 Surface Hydrolysis 182 8.

5.2 Native Digestion 183 8.5.3 Hydrothermal Modification 183 8.6 Thermoplastic Starch 184 8.7 Resistant Starch 184 8.8 Starch Nanocrystals 184 8.9 Ionic Liquid 185 8.

10 Enzyme Selection 185 8.11 Packing Configuration 186 8.12 Chemical Modification 186 8.12.1 Cross-Linking 188 8.12.2 Starch-Graft Copolymer 188 8.12.

2.1 Graft with Vinyl Monomers 189 8.12.2.2 Graft with other Monomers 189 8.12.3 Esterification 190 8.12.

3.1 Inorganic Starch Esters 190 8.12.3.2 Organic Starch Esters 190 8.12.4 Etherification 190 8.12.

5 Dual Modification 191 8.12.6 Other Chemical Modification 191 8.12.6.1 Oxidation 192 8.12.6.

2 Acid Modification 192 8.13 Starch-Based Materials 194 8.13.1 PLA Starch 194 8.13.2 Starch Alginate 194 8.13.3 PCL Starch 194 8.

13.4 Chitosan Starch 195 8.13.5 Starch Clay 195 8.13.6 Starch and DMAEMA 196 8.13.7 Plasticized Starch(PLS)/Poly(Butylene Succinate Co-Butylene Adipate (PBSA) 196 8.

13.8 Gelatin-OSA Starch 197 8.13.9 Chitin and Starch 197 8.13.10 Cashew Nut Shell (CNS) and Chitosan 197 8.14 Applications 198 8.14.

1 Wound Dressing 198 8.14.2 Biomedical 198 8.14.3 Nanomaterial 199 8.14.4 Cancer 199 8.14.

5 Starch Film 200 8.14.6 Gene Delivery 200 8.14.7 Transdermal Delivery 200 8.14.8 Resistive Switch Memory 201 8.14.

9 Oral Drug Delivery 201 8.14.10 Waste Water Treatment 202 8.14.11 Heavy Metal Removal 202 8.14.12 Dry Removal 204 Acknowledgement 205 References 205 9 Synthesized Cu2Zn1-xCdxSnS4 Quinternary Alloys Nanostructures for Optoelectronic Applications 209 Y. Al-Douri and A.

S. Ibraheam 9.1 Introduction 210 9.2 Experimental Process 211 9.3 Results and Discussion 213 9.4 Conclusions 219<.