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Surface Modification of Polymers Methods and Applications

Langue : Anglais

Coordonnateurs : Pinson Jean, Thiry Damien

Couverture de l’ouvrage Surface Modification of Polymers
A guide to modifying and functionalizing the surfaces of polymers

Surface Modification of Polymers is an essential guide to the myriad methods that can be employed to modify and functionalize the surfaces of polymers. The functionalization of polymer surfaces is often required for applications in sensors, membranes, medicinal devices, and others. The contributors?noted experts on the topic?describe the polymer surface in detail and discuss the internal and external factors that influence surface properties.

This comprehensive guide to the most important methods for the introduction of new functionalities is an authoritative resource for everyone working in the field. This book explores many applications, including the plasma polymerization technique, organic surface functionalization by initiated chemical vapor deposition, photoinduced functionalization on polymer surfaces, functionalization of polymers by hydrolysis, aminolysis, reduction, oxidation, surface modification of nanoparticles, and many more. Inside, readers will find information on various applications in the biomedical field, food science, and membrane science. This important book:

-Offers a range of polymer functionalization methods for biomedical applications, water filtration membranes, and food science
-Contains discussions of the key surface modification methods, including plasma and chemical techniques, as well as applications for nanotechnology, environmental filtration, food science, and biomedicine
-Includes contributions from a team of international renowned experts

Written for polymer chemists, materials scientists, plasma physicists, analytical chemists, surface physicists, and surface chemists, Surface Modification of Polymers offers a comprehensive and application-oriented review of the important functionalization methods with a special focus on biomedical applications, membrane science, and food science.

Introduction xiii

1 The Surface of Polymers 1
Rosica Mincheva and Jean-Marie Raquez

1.1 Introduction 1

1.2 The Surface of Polymers 2

1.2.1 Definition of a Polymer Surface 2

1.2.2 Factors Determining a Polymer Surface 3

1.2.2.1 Internal Factors 3

1.2.2.2 External Factors 4

1.2.3 The Polymer Surface at a Microscopic Level 11

1.3 Properties of Polymer Surfaces at Interfaces 12

1.3.1 Surface Wettability 13

1.3.2 Surface Thermal Properties 15

1.3.2.1 Surface Tg 15

1.3.2.2 Surface Crystallization 17

1.4 Experimental Methods for Investigating Polymer Surfaces at Interfaces 21

1.5 Conclusions 21

References 21

Part I Gas Phase Methods 31

2 Surface Treatment of Polymers by Plasma 33
Pieter Cools, Laura Astoreca, Parinaz Saadat Esbah Tabaei, Monica Thukkaram, Herbert De Smet, Rino Morent, and Nathalie De Geyter

2.1 Plasma: An Introduction 33

2.1.1 Definition 33

2.1.2 Thermal Versus Nonthermal Plasma 34

2.1.3 The Formation of Nonthermal Plasma 35

2.1.4 Plasma Generation and Operating Conditions 37

2.1.4.1 Different Methods of Plasma Generation 37

2.1.4.2 DC Discharges 38

2.1.4.3 DC Pulsed Discharges 38

2.1.4.4 RF and MW Discharges 38

2.1.4.5 Dielectric Barrier Discharge (DBD) 39

2.1.4.6 Atmospheric Pressure Plasma Jet (APPJ) 40

2.1.4.7 Gliding Arc 41

2.1.5 Nonthermal Plasma for Polymer Surface Treatment 41

2.2 Applications of Plasma Surface Activation of Polymers 43

2.2.1 Adhesion Improvement 43

2.2.2 Packaging and Textile Applications 47

2.2.2.1 Printability Enhancement 47

2.2.2.2 Dyeability Improvement 47

2.2.2.3 Mass Transfer Changes 49

2.2.3 Biomedical Applications 50

2.2.3.1 Inert Synthetic Polymers 50

2.2.3.2 Biodegradable Polymers 53

2.3 Plasma Grafting 56

2.4 Hydrophobic Recovery 59

2.5 Conclusion 61

References 61

3 A Joint Mechanistic Description of Plasma Polymers Synthesized at Low and Atmospheric Pressure 67
Damien Thiry, François Reniers, and Rony Snyders

3.1 Introduction 67

3.2 Plasma Polymerization 69

3.2.1 Plasma Fundamentals 70

3.2.2 Growth Mechanism 72

3.3 Probing the Plasma Chemistry 83

3.3.1 Optical Emission Spectroscopy 84

3.3.2 Mass Spectrometry 87

3.4 Conclusions 96

References 97

4 Organic Surface Functionalization by Initiated CVD (iCVD) 107
Karen K. Gleason

4.1 Introduction 107

4.2 Mechanistic Principles of iCVD 108

4.3 Functional, Surface Reactive, and Responsive Organic Films Prepared by iCVD 113

4.4 Interfacial Engineering with iCVD: Adhesion and Grafting 127

4.5 Reactors for Synthesizing Organic Films by iCVD 128

4.6 Summary 129

References 130

5 Atomic Layer Deposition and Vapor Phase Infiltration 135
Mark D. Losego and Qing Peng

5.1 Atomic Layer Deposition Versus Vapor Phase Infiltration 135

5.2 Atomic Layer Deposition (ALD) on Polymers 138

5.2.1 Chemical Mechanisms of ALD 138

5.2.2 ALD on Polymers with Dense –OH Groups: Cellulose and Poly(vinyl alcohol) 140

5.2.3 ALD onto “Unreactive” Polymer Substrates 141

5.2.4 Applications of ALD Coated Polymers 143

5.2.4.1 ALD Coated Cotton Fibers 143

5.2.4.2 Applications for ALD Coatings on Other Polymers 144

5.3 Vapor Phase Infiltration of Polymers 145

5.3.1 Processing Thermodynamics and Kinetics of VPI 145

5.3.1.1 Thermodynamics of Vapor-Phase Precursor Sorption into Polymers 145

5.3.1.2 Kinetics of Precursor Diffusion During VPI 147

5.3.1.3 VPI Processes Incorporating Both Penetrant Diffusion and Reaction 148

5.3.1.4 Measuring the Thermodynamics and Kinetics of a VPI Process 149

5.3.2 Applications of Vapor Phase Infiltrated Polymers 150

5.3.2.1 Altering Mechanical Performance 150

5.3.2.2 Contrasting Agent for Multi-phase Polymer Imaging 152

5.3.2.3 Improved Chemical Resistance 152

5.3.2.4 Patterning for Microsystems 153

5.3.2.5 Vapor Diffusion Barriers 154

5.3.2.6 Conducting Polymers and Hybrid Photovoltaic Cells 154

5.3.2.7 Other Application Spaces 155

5.4 Summary and Future Outlook for ALD and VPI on Polymers 156

References 156

Part II UV and Related Methods 161

6 Photoinduced Functionalization on Polymer Surfaces 163
Kazuhiko Ishihara

6.1 Introduction 163

6.2 Improving the Surface Properties of Polymeric Materials by Photoirradiation 165

6.3 Photoreaction of Polymers with Other Polymers 166

6.3.1 Photoinduced Chemical Reaction Between Polymers 166

6.3.2 Photoinduced Grafting at the Polymer Surface 168

6.3.3 Preparation of High-functionality Surface by Photoinduced Graft Polymerization 169

6.3.4 Application of Photoinduced Grafting Process to Artificial Organs 172

6.4 Self-initiated Photoinduced Graft Polymerization 174

6.4.1 Poly(ether ketone) as Photoinitiator for Graft Polymerization 174

6.4.2 Effects of Inorganic Salts on Photoinduced Graft Polymerization in an Aqueous System 178

6.5 Conclusion and Future Perspective 180

References 181

7 𝜸-Rays and Ions Irradiation 185
Alejandro Ramos-Ballesteros, Victor H. Pino-Ramos, Felipe López-Saucedo,Guadalupe G. Flores-Rojas, and Emilio Bucio

7.1 𝛾-Rays and Ions Irradiation 185

7.2 Ionizing Radiation Sources 186

7.3 𝛾-Ray-Induced Modifications 186

7.3.1 Grafting Modifications 186

7.3.1.1 Radiation-induced Grafting Methods 188

7.3.1.2 Ionic Grafting 192

7.3.1.3 RAFT-graft Polymerization 193

7.3.1.4 Applications 194

7.3.2 Cross-linking 197

7.3.2.1 𝛾-Ray Cross-linking Modifications 199

7.3.2.2 Cross-linking with Additives 200

7.3.2.3 Industrial Applications 201

7.4 Heavy Ion-Induced Modifications 202

7.4.1 Polymers 204

7.5 Conclusions 205

Acknowledgments 206

References 206

Part III Chemical Methods 211

8 Functionalization of Polymers by Hydrolysis, Aminolysis, Reduction, Oxidation, and Some Related Reactions 213
Dardan Hetemi and Jean Pinson

8.1 Hydrolysis and Aminolysis 213

8.1.1 PLA and Polyesters 213

8.1.2 Hydrolysis 214

8.1.3 Aminolysis 214

8.1.4 PCL 215

8.1.5 PET 216

8.1.6 PMMA 216

8.1.7 Cellulose 217

8.2 Chemical Reduction 220

8.2.1 PEEK 220

8.2.2 PET 225

8.2.3 PMMA 227

8.2.4 PC 227

8.2.5 PTFE 229

8.3 Chemical Oxidation 231

8.4 Non-covalent Surface Modification 234

8.5 Conclusion 235

References 236

9 Functionalization of Polymers by Reaction of Radicals, Nitrenes, and Carbenes 241
Jean Pinson

9.1 Functionalization of Polymers by Reaction of Radicals 241

9.1.1 Peroxides as Radical Initiators 241

9.1.2 Hydrogen Peroxides as Radical Initiator 244

9.1.3 Persulfates as Radical Initiators 246

9.1.4 Oxygen as Radical Initiator 248

9.1.5 Azo Compounds as Radical Initiator 249

9.1.6 Diazonium Salts as Radical Initiator 250

9.1.6.1 Polypyrrole 251

9.1.6.2 Polyaniline 251

9.1.6.3 Poly(3,4-ethylenedioxythiophene)–Poly(styrenesulfonate) (PEDOT:PSS) 253

9.1.6.4 Polymethylmethacrylate (PMMA) 254

9.1.6.5 Polypropylene (PP) 255

9.1.6.6 Polyvinyl Chloride 255

9.1.6.7 Cyclic Olefin Copolymers (COC) 256

9.1.6.8 Polyetheretherketone (PEEK) 256

9.1.6.9 PET (Polyethylene Terephthalate) 257

9.1.6.10 Polysulfone Membranes 258

9.1.6.11 Cation Exchange Membranes 258

9.1.6.12 Fluoro Polymers 259

9.1.6.13 Natural Polymers 260

9.1.7 Alkyl Halides as Radical Initiator 260

9.2 Surface Modification of Polymers with Carbenes and Nitrenes 260

9.2.1 Carbenes 261

9.2.2 Nitrenes 264

9.3 Conclusion 267

References 268

10 Surface Modification of Polymeric Substrates with Photo- and Sonochemically Designed Macromolecular Grafts 273
Fatima Mousli, Youssef Snoussi, Ahmed M. Khalil, Khouloud Jlassi, Ahmed Mekki, and Mohamed M. Chehimi

10.1 Introduction 273

10.1.1 Context 273

10.1.2 Scope of the Chapter 274

10.2 Surface-confined Radical Photopolymerization of Insulating Vinylic and Other Monomers 274

10.2.1 Type I and Type II Photoinitiation Systems 275

10.2.2 Simultaneous Photoinduced Electron Transfer and Free Radical Polymerization Confined to Surfaces 282

10.2.3 Surface-initiated Photoiniferter 284

10.2.4 “Brushing Up from Anywhere” Using Polydopamine Thin Adhesive Coatings 284

10.2.5 Recent Trends in Surface-confined Photopolymerization (CRP) 287

10.3 Surface-confined Photopolymerization of Conjugated Monomers 289

10.3.1 Polypyrrole 290

10.3.1.1 Mechanisms of Photopolymerization of Pyrrole 290

10.3.1.2 Substrates for in Situ Photoinduced Polymerization of Pyrrole and Potential Applications 291

10.3.2 Polyaniline 294

10.3.2.1 Mechanisms of Photopolymerization of Aniline 294

10.3.2.2 Substrates for in Situ Photoinduced Polymerization of Aniline 298

10.4 Surface-confined Sonochemical Polymerization of Conjugated and Vinylic Monomers 298

10.4.1 Insights into Sonochemistry: Origin of the Phenomenon and Mechanism of Polymer Synthesis 298

10.4.2 Ultrasound-assisted Polymerization or Polymer Deposition over Organic Polymeric Substrates 303

10.4.2.1 Sonopolymerization 303

10.4.2.2 Ultrasonic Spray 303

10.4.3 Sonopolymerization over Miscellaneous Types of Surface: Inorganic Polymeric Substrates 305

10.5 Conclusion 306

Acknowledgments 307

References 307

Part IV Applications 317

11 Surface Modification of Nanoparticles: Methods and Applications 319
Gopikrishna Moku, Vijayagopal Raman Gopalsamuthiram, Thomas R. Hoye, and Jayanth Panyam

11.1 Introduction 319

11.2 Polymers Used in the Preparation of Nanoparticles 320

11.3 Common Biodegradable Polymers for Nanoparticle Fabrication 320

11.3.1 Albumin 320

11.3.2 Alginate 320

11.3.2.1 Chitosan 321

11.3.3 Gelatin 322

11.3.4 Poly(lactide-co-glycolide) (PLGA) and Polylactide (PLA) 322

11.3.5 Poly-ε-caprolactone (PCL) 323

11.4 Fabrication of Nanoparticles 323

11.5 Linker Chemistry for Attaching Ligands on Polymeric Nanoparticles 324

11.5.1 Hydrazone Bond Formation 327

11.5.2 Non-covalent Attachment 328

11.6 Surface-functionalized Polymeric Nanoparticles for Drug Delivery Applications 328

11.6.1 Polysaccharides 329

11.6.2 Lipids 329

11.6.3 Aptamers 332

11.6.4 Antibodies 332

11.6.5 Peptides 333

11.6.5.1 Polyethylene Glycol (PEG) 334

11.7 Characterization of Surface-modified Nanoparticles 336

11.7.1 Particle Size 336

11.7.2 Dynamic Light Scattering (DLS) 337

11.7.3 Scanning Electron Microscopy (SEM) 337

11.7.4 Transmission Electron Microscopy (TEM) 339

11.7.5 Surface Charge 339

11.7.6 Surface Hydrophobicity 340

11.7.7 Fourier Transform IR (FTIR) Spectroscopy 341

11.8 Summary/Conclusion 342

References 342

12 Surface Modification of Polymers for Food Science 347
Valentina Siracusa

12.1 Introduction 347

12.2 Physical and Chemical Methods 348

12.2.1 Gas Phase and Radiation 349

12.2.1.1 Gas Phase 349

12.2.1.2 Radiation 350

12.2.2 Liquid and Bulk Phase Methods 352

12.2.2.1 Adsorption Methods 352

12.2.2.2 Desorption Method 352

12.2.3 Interfacial Adhesion of Polymers 353

12.2.4 Grafting and Polymerization 354

12.3 Mechanical Method 354

12.4 Biological Method 354

12.5 Surface Modification of Polymer for Food Packaging 355

12.5.1 Applications 355

12.5.1.1 Surface Sterilization 355

12.5.1.2 Printing 355

12.5.1.3 Mass Transfer 356

12.5.2 Polymers 356

12.6 Conclusion 358

References 359

13 Surface Modification of Water Purification Membranes 363
Anthony Szymczyk, Bart van der Bruggen, and Mathias Ulbricht

13.1 Introduction 363

13.2 Irradiation-Based Direct Polymer Modification 365

13.2.1 Plasma Treatment 365

13.2.2 UV Irradiation 366

13.2.3 Irradiation with High Energy Sources 368

13.3 Coatings 369

13.3.1 Coatings from Gas Phase 369

13.3.2 Coatings from Wet Phase 371

13.4 Grafting Methods 378

13.4.1 Grafting-to 378

13.4.2 Grafting-from 381

13.4.2.1 Plasma-Induced Graft Polymerization 381

13.4.2.2 UV-Induced Grafting 383

13.4.2.3 Grafting Induced by High Energy Radiations 385

13.4.2.4 Grafting Initiated by Chemical/Electrochemical Means 385

13.4.3 Controlled Grafting-from 389

13.5 Conclusion 392

References 394

14 Surface Modification of Polymer Substrates for Biomedical Applications 399
P. Slepicka, N. Slepičková Kasálková, Z. Kolská, and V. Švorčík

14.1 Introduction 399

14.2 Plasma Treatment 400

14.3 Laser Modification 411

14.3.1 Interaction with Cells 411

14.3.2 Sensor Construction 412

14.4 Conclusion 416

Acknowledgments 417

References 417

Index 427

Jean Pinson, PhD, is Professor Emeritus of the Université Paris Diderot. He is interested in the functionalization and modification of polymer surfaces and the surface chemistry of diazonium salts.

Damien Thiry, PhD, is Senior Researcher at the University of Mons (Chimie des Interactions Plasma-Surface (ChIPS)), Belgium.

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