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The Chemistry of Environmental Engineering. Edition No. 1

  • Book

  • 336 Pages
  • June 2020
  • John Wiley and Sons Ltd
  • ID: 5840619

The focus of this book is the chemistry of environmental engineering and its applications, with a special emphasis on the use of polymers in this field. It explores the creation and use of polymers with special properties such as viscoelasticity and interpenetrating networks; examples of which include the creation of polymer-modified asphalt as well as polymers with bacterial adhesion properties.  The text contains the issues of polymerization methods, recycling methods, wastewater treatment, types of contaminants, such as microplastics, organic dyes, and pharmaceutical residues.

After a detailed overview of polymers in Chapter 1, their special properties are discussed in the following chapter. Among the topics is the importance of polymers to water purification procedures, since their use in the formation of reverse osmosis membranes do not show biofouling. Chapter 3 details special processing methods, such as atom transfer radical polymerization, enzymatic polymerization, plasma treatment, and several other methods, can be used to meet the urgent demands of industrial applications.  Chapter 4 addresses the important environmental issue of recycling methods as they relate to several types of materials such as PET bottles, tire rubbers, asphalt compositions, and other engineering resins. And wastewater treatment is detailed in Chapter 5, in which the types of contaminants, such as microplastics, organic dyes and pharmaceutical residues, are described and special methods for their proper removal are detailed along with types of adsorbents, including biosorbents. Still another important issue for environmental engineering chemistry is pesticides. Chapter 6 is a thorough description of the development and fabrication of special sensors for the detection of certain pesticides. A detailed presentation of the electrical uses of polymer-based composites is given in Chapter 7, which include photovoltaic materials, solar cells, energy storage and dielectric applications, light-emitting polymers, and fast-charging batteries. And recent issues relating to food engineering, such as food ingredient tracing, protein engineering, biosensors and electronic tongues, are presented in Chapter 8. Finally, polymers used for medical applications are described in Chapter 9. These applications include drug delivery, tissue engineering, porous coatings and also the special methods used to fabricate such materials.

Table of Contents

Preface xi

1 Special Polymers 1

1.1 Poly(ethylene) 1

1.1.1 Metallocene Poly(ethylene) 1

1.1.2 Geomembranes 6

1.2 Poly(styrene) 7

1.2.1 Syndiotactic Poly(styrene) 7

1.3 Poly(ethylene terephthalate) 11

1.3.1 Blends of Poly(ethylene terephthalate) and Poly(phenylene sulfide) 11

1.4 Silicones 12

1.4.1 Silicon Nanocrystals and Silicon-Polymer Hybrids 12

1.4.2 Surfactants 13

1.5 Self-healing Polymers 25

1.5.1 Multiphasic Copolymer 26

1.5.2 Hydrophobic Coatings 28

1.5.3 Microcapsule Based Self-Healing 28

1.5.4 Tunable Mechanical Strengths 29

1.5.5 Bioinspired Pathways 30

1.6 Fibers and Smart Polymers 32

1.6.1 Natural Fiber Reinforced Polymer Composites 32

1.6.2 Shape Memory Systems 35

1.6.3 Smart Polymers 41

1.7 Porous Materials 42

1.7.1 Preparation Methods 42

1.7.2 Polymer Foams 48

1.7.3 Porous Polymer Monoliths 50

1.7.4 Concrete 51

References 54

2 Special Properties of Polymers 63

2.1 Viscoelasticity 63

2.2 Impact response of Hybrid Carbon/Glass Fiber Reinforced Polymer Composites 63

2.3 Mechanical Properties 64

2.3.1 Real Elastic Network Theory 64

2.3.2 Interpenetrating Polymer Network Hydrogels 65

2.3.3 Flax Fabric Reinforced Polymer 66

2.3.4 Asphalt 66

2.4 Bacterial Adhesion 70

2.4.1 Influence of Stiffness 72

2.4.2 Bioactive Sulfone Polymers 74

2.4.3 Functionalized Dopamine 82

2.4.4 Sub-micrometer Structures 83

2.4.5 Mechanically Modulated Microgel Coatings 85

2.4.6 Conductive Polymers 86

2.4.7 Reverse Osmosis Membranes 87

References 94

3 Processing Methods 99

3.1 Radiation Processing 99

3.2 Additive Manufacturing 99

3.3 Atom Transfer Radical Polymerization 101

3.3.1 Vinyl Macromonomers of Poly(styrene) 101

3.3.2 Ultrasound Atom Transfer Radical Polymerization 102

3.3.3 Near-Infrared Sensitized Photoinduced Atom-Transfer Radical Polymerization 103

3.4 Reversible Addition-Fragmentation Chain Transfer Polymerization 105

3.5 Enzymatic Polymerization 108

3.6 Surface Patterning 111

3.6.1 Nonthermal Plasma Technology 111

3.7 Friction Welding 113

3.7.1 ABS and Poly(amide)s 114

3.8 Interfacial Engineering 117

3.9 Plasma Treatment 118

3.9.1 Mineralization of Plasma Treated Polymer Surfaces 118

3.9.2 Wetting Properties 119

3.9.3 Vapor Phase Graft Polymerization 121

3.9.4 Effect of Plasma Treatment Frequency 123

3.9.5 Plasma Treatment in Textile Industry 124

3.9.6 Antimicrobial Surfaces 126

3.9.7 Non-Thermal Plasma Treatment of Agricultural Seeds 130

3.9.8 Special Materials 132

References 136

4 Recycling 143

4.1 Recycling Methods 143

4.1.1 Primary Recycling 143

4.1.2 Secondary Recycling 143

4.1.3 Tertiary Recycling 144

4.1.4 Quaternary Recycling 144

4.1.5 Melt Filtration 145

4.1.6 Hydrothermal Recycling 148

4.1.7 Quality of Postconsumer Plastics 149

4.2 Materials 151

4.2.1 Poly(propylene) Waste 151

4.2.2 PET Bottles 152

4.2.3 Engineering Epoxy Resin 156

4.2.4 Carbon Nanotube-Filled Polycarbonate 157

4.2.5 Asphalt Compositions 158

4.2.6 Tire Rubbers 160

References 161

5 Wastewater Treatment 165

5.1 Properties and Contaminants 165

5.1.1 Microplastics 167

5.1.2 Organic Dyes 168

5.1.3 Pharmaceutical Residues in Wastewater 169

5.1.4 Passively Aerated Biological Filter 171

5.2 Adsorbents 173

5.2.1 Activated Carbon 173

5.2.2 Adsorbent Regeneration 176

5.2.3 Ultrasound-assisted treatment 177

5.2.4 Praseodymium Molybdate 178

5.2. Biosorbents 179

References 181

6 Pesticides 183

6.1 Pesticide Carriers 183

6.2 PCL Nanocapsules 184

6.3 Self-Decontamination Mechanisms 185

6.4 Controlled Release of Pesticides 186

6.4.1 PVA-Starch Composite Films 187

6.4.2 PLA Nanofibers 188

6.4.3 PBSU and PLA Nanofibers 188

6.4.4 Poly(3-hydroxybutyrate) 189

6.5 Sensors 190

6.5.1 Biosensor for Dichlorvos 190

6.5.2 Biosensor for Carbaryl 192

6.5.3 Voltammetric Method for Ethyl Paraoxon 192

6.5.4 Nitrogen Doped Graphene Electrode 193

6.5.5 Molecularly Imprinted Sensor 194

6.5.6 Ecotoxicity Evaluation 195

References 197

7 Electrical Uses 199

7.1 Photovoltaic Materials 199

7.2 Solar Cells 200

7.3 Energy Storage and Dielectric Applications 200

7.3.1 Polymer Nanocomposites 201

7.3.2 Multiwall Carbon Nanotubes 207

7.3.3 High-Temperature Dielectric Materials 208

7.4 Light Emitting Polymers 208

7.4.1 Circularly Polarized Light 208

7.4.2 Polymer Types 210

7.4.3 Color Management 213

7.4.4 Light-Emitting Electrochemical Cells 222

7.5 Fast Charging Batteries 228

7.5.1 Charging Stages 230

7.5.2 Increasing the Cycling Lifetime 232

7.5.3 Lithium-Ion Batteries 232

7.6 Electrical Power Cable Engineering 234

7.6.1 Carbon Nanotube Cables 235

7.6.2 High Voltage Alternating Current Cables for Subsea Transmission 235

7.6.3 Biodegradable Polymer Cables 238

References 238

8 Food Engineering 245

8.1 Software 245

8.1.1 GUI Software Packages 245

8.1.2 Food Ingredient Tracing 246

8.1.3 Microbial Growth 246

8.2 Materials 247

8.2.1 Microbial Biopolymers 247

8.2.2 Marine Polysaccharides 247

8.3 Protein Engineering 249

8.4 Instrumentation and Sensors 250

8.4.1 Biosensors 250

8.4.2 Electronic Tongues 253

8.4.3 Microwave Methods 254

8.4.4 Optoelectronic Sensor 256

8.4.5 Digital Image Analysis 257

8.5 Ultrasonic Methods 258

8.5.1 Special Applications 259

8.5.2 Composition of Meat 259

8.5.3 Flour Quality 261

8.5.4 Porosity of Bread 262

8.5.5 Dairy Products 263

References 265

9 Medical Uses 269

9.1 Drug Delivery 269

9.2 Porous Bioresorbable Polymers 269

9.3 Tissue Engineering 274

9.3.1 Biomedical Materials 274

9.3.2 Electrically Conducting Polymer 279

9.3.3 Bioactive Glass 280

9.3.4 Glass-based Coatings 287

9.3.5 Hard Tissue Implants 290

9.3.6 Membranes 294

9.3.7 Textile-based Technologies 295

9.3.8 Improvement of Cell Adhesion 296

9.3.9 Solvent Free Fabrication 297

9.3.10 Stereolithographic 3D Printing 298

9.3.11 Extrusion-Based 3D Printing 299

References 302

Index 307

Acronyms 307

Chemicals 311

General Index 315

Authors

Johannes Karl Fink University of Leoben, Austria.