Description

Book Synopsis
Proton conduction can be found in many different solid materials, from organic polymers at room temperature to inorganic oxides at high temperature. Solid state proton conductors are of central interest for many technological innovations, including hydrogen and humidity sensors, membranes for water electrolyzers and, most importantly, for high-efficiency electrochemical energy conversion in fuel cells.

Focusing on fundamentals and physico-chemical properties of solid state proton conductors, topics covered include:

  • Morphology and Structure of Solid Acids
  • Diffusion in Solid Proton Conductors by Nuclear Magnetic Resonance Spectroscopy
  • Structure and Diffusivity by Quasielastic Neutron Scattering
  • Broadband Dielectric Spectroscopy
  • Mechanical and Dynamic Mechanical Analysis of Proton-Conducting Polymers
  • Ab initio Modeling of Transport and Structure
  • Perfluorinated Sulfonic Acids
  • Proton-Conducting Aromatic

    Table of Contents
    Preface xi

    About the Editors xiii

    Contributing Authors xv

    1 Introduction and Overview: Protons, the Nonconformist Ions 1
    Maria Luisa Di Vona and Philippe Knauth

    1.1 Brief History of the Field 2

    1.2 Structure of This Book 2

    References 4

    2 Morphology and Structure of Solid Acids 5
    Habib Ghobarkar, Philippe Knauth and Oliver Sch€af

    2.1 Introduction 5

    2.1.1 Preparation Technique of Solid Acids 5

    2.1.2 Imaging Technique with the Scanning Electron Microscope 6

    2.2 Crystal Morphology and Structure of Solid Acids 8

    2.2.1 Hydrohalic Acids 8

    2.2.2 Main Group Element Oxoacids 10

    2.2.3 Transition Metal Oxoacids 20

    2.2.4 Carboxylic Acids 22

    References 24

    3 Diffusion in Solid Proton Conductors: Theoretical Aspects and Nuclear Magnetic Resonance Analysis 25
    Maria Luisa Di Vona, Emanuela Sgreccia and Sebastiano Tosto

    3.1 Fundamentals of Diffusion 25

    3.1.1 Phenomenology of Diffusion 26

    3.1.2 Solutions of the Diffusion Equation 35

    3.1.3 Diffusion Coefficients and Proton Conduction 37

    3.1.4 Measurement of the Diffusion Coefficient 38

    3.2 Basic Principles of NMR 40

    3.2.1 Description of the Main NMR Techniques Used in Measuring Diffusion Coefficients 42

    3.3 Application of NMR Techniques 47

    3.3.1 Polymeric Proton Conductors 47

    3.3.2 Inorganic Proton Conductors 58

    3.4 Liquid Water Visualization in Proton-Conducting Membranes by Nuclear Magnetic Resonance Imaging 62

    3.5 Conclusions 66

    References 67

    4 Structure and Diffusivity in Proton-Conducting Membranes Studied by Quasielastic Neutron Scattering 71
    Rolf Hempelmann

    4.1 Survey 71

    4.2 Diffusion in Solids and Liquids 73

    4.3 Quasielastic Neutron Scattering: A Brief Introduction 76

    4.4 Proton Diffusion in Membranes 82

    4.4.1 Microstructure by Means of SAXS and SANS 82

    4.4.2 Proton Conductivity and Water Diffusion 89

    4.4.3 QENS Studies 90

    4.5 Solid State Proton Conductors 95

    4.5.1 Aliovalently Doped Perovskites 96

    4.5.2 Hydrogen-Bonded Systems 101

    4.6 Concluding Remarks 104

    References 104

    5 Broadband Dielectric Spectroscopy: A Powerful Tool for the Determination of Charge Transfer Mechanisms in Ion Conductors 109
    Vito Di Noto, Guinevere A. Giffin, Keti Vezzu`, Matteo Piga and Sandra Lavina

    5.1 Basic Principles 110

    5.1.1 The Interaction of Matter with Electromagnetic Fields: The Maxwell Equations 110

    5.1.2 Electric Response in Terms of e*m ðoÞ, s*m ðoÞ, and Z*mðoÞ 111

    5.2 Phenomenological Background of Electric Properties in a Time-Dependent Field 114

    5.2.1 Polarization Events 114

    5.3 Theory of Dielectric Relaxation 127

    5.3.1 Dielectric Relaxation Modes of Macromolecular Systems 129

    5.3.2 A General Equation for the Analysis in the Frequency Domain of s(o) and e(o) 132

    5.4 Analysis of Electric Spectra 132

    5.5 Broadband Dielectric Spectroscopy Measurement Techniques 141

    5.5.1 Measurement Systems 142

    5.5.2 Contacts 158

    5.5.3 Calibration 165

    5.5.4 Calibration in Parallel Plate Methods 165

    5.5.5 Measurement Accuracy 172

    5.6 Concluding Remarks 180

    References 180

    6 Mechanical and Dynamic Mechanical Analysis of Proton-Conducting Polymers 185
    Jean-Franc¸ois Chailan, Mustapha Khadhraoui and Philippe Knauth

    6.1 Introduction 185

    6.1.1 Molecular Configurations: The Morphology and Microstructure of Polymers 185

    6.1.2 Molecular Motions 187

    6.1.3 Glass Transition and Other Molecular Relaxations 188

    6.2 Methodology of Uniaxial Tensile Tests 191

    6.2.1 Elasticity and Young’s Modulus E 192

    6.2.2 Elasticity and Shear Modulus G 195

    6.2.3 Elasticity and Cohesion Energy 196

    6.3 Relaxation and Creep of Polymers 197

    6.3.1 Stress Relaxation of Polymers 198

    6.3.2 Creep of Polymers 199

    6.4 Engineering Stress–Strain Curves of Polymers 201

    6.4.1 True Stress–Strain Curve for Plastic Flow and Toughness of Polymers 203

    6.4.2 Behavior of Composite Membranes 204

    6.4.3 Behavior in the Glassy Regime 205

    6.4.4 Influence of the Rate of Deformation 206

    6.4.5 Effect of Temperature on Mechanical Properties 209

    6.4.6 Thermal Strain 210

    6.5 Stress–Strain Tensile Tests of Proton-Conducting Ionomers 211

    6.5.1 Influence of Heat Treatment and Cross-Linking 212

    6.5.2 Behavior of Composites 214

    6.5.3 Conclusions 215

    6.6 Dynamic Mechanical Analysis (DMA) of Polymers 217

    6.6.1 Principle of Measurement 217

    6.6.2 Molecular Motions and Dynamic Mechanical Properties 218

    6.6.3 Experimental Considerations: How Does the Instrument Work? 219

    6.6.4 Parameters of Dynamic Mechanical Analysis 220

    6.7 The DMA of Proton-Conducting Ionomers 222

    6.7.1 Perfluorosulfonic Acid Ionomer Membranes 222

    6.7.2 Nonfluorinated Membranes 225

    6.7.3 Organic–Inorganic Composite (or Hybrid) Membranes 230

    Glossary 235

    References 236

    7 Ab Initio Modeling of Transport and Structure of Solid State Proton Conductors 241
    Jeffrey K. Clark II and Stephen J. Paddison

    7.1 Introduction 241

    7.2 Theoretical Methods 244

    7.2.1 Ab Initio Electronic Structure 244

    7.2.2 Ab Initio Molecular Dynamics (AIMD) 248

    7.2.3 Empirical Valence Bond (EVB) Models 249

    7.3 Polymer Electrolyte Membranes 251

    7.3.1 Local Microstructure 251

    7.3.2 Proton Dissociation, Transfer, and Separation 258

    7.4 Crystalline Proton Conductors and Oxides 279

    7.4.1 Crystalline Proton Conductors 279

    7.4.2 Oxides 284

    7.5 Concluding Remarks 290

    References 290

    8 Perfluorinated Sulfonic Acids as Proton Conductor Membranes 295
    Giulio Alberti, Riccardo Narducci and Maria Luisa Di Vona

    8.1 Introduction on Polymer Electrolyte Membranes for Fuel Cells 295

    8.2 General Properties of Polymer Electrolyte Membranes 296

    8.2.1 Ion Exchange of Polymers Electrolytes in H þ Form 297

    8.3 Perfluorinated Membranes Containing Superacid –SO3H Groups 303

    8.3.1 Nafion Preparation 304

    8.3.2 Nafion Morphology 304

    8.3.3 Nafion Water Uptake in Liquid Water at Different Temperatures 306

    8.3.4 Water-Vapor Sorption Isotherms of Nafion 307

    8.3.5 Curves T/nc for Nafion 117 Membranes in H þ Form 308

    8.3.6 Water Uptake and Tensile Modulus of Nafion 311

    8.3.7 Colligative Properties of Inner Proton Solutions in Nafion 313

    8.3.8 Thermal Annealing of Nafion 315

    8.3.9 MCPI Method 315

    8.3.10 Proton Conductivity of Nafion 319

    8.4 Some Information on Dow and on Recent AquivionIonomers 321

    8.5 Instability of Proton Conductivity of Highly Hydrated PFSA Membranes 321

    8.6 Composite Nafion Membranes 323

    8.6.1 Silica-Filled Ionomer Membranes 323

    8.6.2 Metal Oxide-Filled Nafion Membranes 324

    8.6.3 Layered Zirconium Phosphate- and Zirconium Phosphonate-Filled Ionomer Membranes 324

    8.6.4 Heteropolyacid-Filled Membranes 325

    8.7 Some Final Remarks and Conclusions 326

    References 327

    9 Proton Conductivity of Aromatic Polymers 331
    Baijun Liu and Michael D. Guiver

    9.1 Introduction 331

    9.2 Synthetic Strategies of the Various Acid-Functionalized Aromatic Polymers with Proton Transport Ability 332

    9.2.1 Sulfonated Poly(arylene ether)s 332

    9.2.2 Sulfonated Polyimides 341

    9.2.3 Other Aromatic Polymers as PEMs 344

    9.3 Approaches to Enhance Proton Conductivity 349

    9.3.1 Nanophase-Separated Microstructures Containing Proton-Conducting Channels 349

    9.3.2 Replacement of –Ph-SO3H by –CF2 –SO3H 353

    9.3.3 Synthesis of High-IEC PEMs 355

    9.3.4 Composite Membranes 356

    9.4 Balancing Proton Conductivity, Dimensional Stability, and Other Properties 358

    9.5 Electrochemical Performance of Aromatic Polymers 361

    9.5.1 PEMFC Performance 362

    9.5.2 DMFC Performance 363

    9.6 Summary 363

    References 365

    10 Inorganic Solid Proton Conductors 371
    Philippe Knauth and Maria Luisa Di Vona

    10.1 Fundamentals of Ionic Conduction in Inorganic Solids 371

    10.1.1 Defect Concentrations 372

    10.1.2 Defect Mobilities 373

    10.1.3 Kr€oger–Vink Nomenclature 373

    10.1.4 Ionic Conduction in the Bulk: Hopping Model 376

    10.2 General Considerations on Inorganic Solid Proton Conductors 378

    10.2.1 Classification of Solid Proton Conductors 379

    10.3 Low-Dimensional Solid Proton Conductors: Layered and Porous Structures 381

    10.3.1 b- and b00-Alumina-Type 381

    10.3.2 Layered Metal Hydrogen Phosphates 382

    10.3.3 Micro- and Mesoporous Structures 384

    10.4 Three-Dimensional Solid Proton Conductors: “Quasi-Liquid” Structures 385

    10.4.1 Solid Acids 385

    10.4.2 Acid Salts 385

    10.4.3 Amorphous and Gelled Oxides and Hydroxides 387

    10.5 Three-Dimensional Solid Proton Conductors: Defect Mechanisms in Oxides 387

    10.5.1 Perovskite-Type Oxides 388

    10.5.2 Other Structure Types 393

    10.6 Conclusion 394

    References 395

    Index 399

Solid State Proton Conductors

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    A Hardback by Philippe Knauth, Maria Luisa Di Vona

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      Publisher: John Wiley & Sons Inc
      Publication Date: 03/02/2012
      ISBN13: 9780470669372, 978-0470669372
      ISBN10: 0470669373
      Also in:
      Chemistry Electronics and communications engineering Mechanical engineering and materials

      Description

      Book Synopsis
      Proton conduction can be found in many different solid materials, from organic polymers at room temperature to inorganic oxides at high temperature. Solid state proton conductors are of central interest for many technological innovations, including hydrogen and humidity sensors, membranes for water electrolyzers and, most importantly, for high-efficiency electrochemical energy conversion in fuel cells.

      Focusing on fundamentals and physico-chemical properties of solid state proton conductors, topics covered include:

      • Morphology and Structure of Solid Acids
      • Diffusion in Solid Proton Conductors by Nuclear Magnetic Resonance Spectroscopy
      • Structure and Diffusivity by Quasielastic Neutron Scattering
      • Broadband Dielectric Spectroscopy
      • Mechanical and Dynamic Mechanical Analysis of Proton-Conducting Polymers
      • Ab initio Modeling of Transport and Structure
      • Perfluorinated Sulfonic Acids
      • Proton-Conducting Aromatic

        Table of Contents
        Preface xi

        About the Editors xiii

        Contributing Authors xv

        1 Introduction and Overview: Protons, the Nonconformist Ions 1
        Maria Luisa Di Vona and Philippe Knauth

        1.1 Brief History of the Field 2

        1.2 Structure of This Book 2

        References 4

        2 Morphology and Structure of Solid Acids 5
        Habib Ghobarkar, Philippe Knauth and Oliver Sch€af

        2.1 Introduction 5

        2.1.1 Preparation Technique of Solid Acids 5

        2.1.2 Imaging Technique with the Scanning Electron Microscope 6

        2.2 Crystal Morphology and Structure of Solid Acids 8

        2.2.1 Hydrohalic Acids 8

        2.2.2 Main Group Element Oxoacids 10

        2.2.3 Transition Metal Oxoacids 20

        2.2.4 Carboxylic Acids 22

        References 24

        3 Diffusion in Solid Proton Conductors: Theoretical Aspects and Nuclear Magnetic Resonance Analysis 25
        Maria Luisa Di Vona, Emanuela Sgreccia and Sebastiano Tosto

        3.1 Fundamentals of Diffusion 25

        3.1.1 Phenomenology of Diffusion 26

        3.1.2 Solutions of the Diffusion Equation 35

        3.1.3 Diffusion Coefficients and Proton Conduction 37

        3.1.4 Measurement of the Diffusion Coefficient 38

        3.2 Basic Principles of NMR 40

        3.2.1 Description of the Main NMR Techniques Used in Measuring Diffusion Coefficients 42

        3.3 Application of NMR Techniques 47

        3.3.1 Polymeric Proton Conductors 47

        3.3.2 Inorganic Proton Conductors 58

        3.4 Liquid Water Visualization in Proton-Conducting Membranes by Nuclear Magnetic Resonance Imaging 62

        3.5 Conclusions 66

        References 67

        4 Structure and Diffusivity in Proton-Conducting Membranes Studied by Quasielastic Neutron Scattering 71
        Rolf Hempelmann

        4.1 Survey 71

        4.2 Diffusion in Solids and Liquids 73

        4.3 Quasielastic Neutron Scattering: A Brief Introduction 76

        4.4 Proton Diffusion in Membranes 82

        4.4.1 Microstructure by Means of SAXS and SANS 82

        4.4.2 Proton Conductivity and Water Diffusion 89

        4.4.3 QENS Studies 90

        4.5 Solid State Proton Conductors 95

        4.5.1 Aliovalently Doped Perovskites 96

        4.5.2 Hydrogen-Bonded Systems 101

        4.6 Concluding Remarks 104

        References 104

        5 Broadband Dielectric Spectroscopy: A Powerful Tool for the Determination of Charge Transfer Mechanisms in Ion Conductors 109
        Vito Di Noto, Guinevere A. Giffin, Keti Vezzu`, Matteo Piga and Sandra Lavina

        5.1 Basic Principles 110

        5.1.1 The Interaction of Matter with Electromagnetic Fields: The Maxwell Equations 110

        5.1.2 Electric Response in Terms of e*m ðoÞ, s*m ðoÞ, and Z*mðoÞ 111

        5.2 Phenomenological Background of Electric Properties in a Time-Dependent Field 114

        5.2.1 Polarization Events 114

        5.3 Theory of Dielectric Relaxation 127

        5.3.1 Dielectric Relaxation Modes of Macromolecular Systems 129

        5.3.2 A General Equation for the Analysis in the Frequency Domain of s(o) and e(o) 132

        5.4 Analysis of Electric Spectra 132

        5.5 Broadband Dielectric Spectroscopy Measurement Techniques 141

        5.5.1 Measurement Systems 142

        5.5.2 Contacts 158

        5.5.3 Calibration 165

        5.5.4 Calibration in Parallel Plate Methods 165

        5.5.5 Measurement Accuracy 172

        5.6 Concluding Remarks 180

        References 180

        6 Mechanical and Dynamic Mechanical Analysis of Proton-Conducting Polymers 185
        Jean-Franc¸ois Chailan, Mustapha Khadhraoui and Philippe Knauth

        6.1 Introduction 185

        6.1.1 Molecular Configurations: The Morphology and Microstructure of Polymers 185

        6.1.2 Molecular Motions 187

        6.1.3 Glass Transition and Other Molecular Relaxations 188

        6.2 Methodology of Uniaxial Tensile Tests 191

        6.2.1 Elasticity and Young’s Modulus E 192

        6.2.2 Elasticity and Shear Modulus G 195

        6.2.3 Elasticity and Cohesion Energy 196

        6.3 Relaxation and Creep of Polymers 197

        6.3.1 Stress Relaxation of Polymers 198

        6.3.2 Creep of Polymers 199

        6.4 Engineering Stress–Strain Curves of Polymers 201

        6.4.1 True Stress–Strain Curve for Plastic Flow and Toughness of Polymers 203

        6.4.2 Behavior of Composite Membranes 204

        6.4.3 Behavior in the Glassy Regime 205

        6.4.4 Influence of the Rate of Deformation 206

        6.4.5 Effect of Temperature on Mechanical Properties 209

        6.4.6 Thermal Strain 210

        6.5 Stress–Strain Tensile Tests of Proton-Conducting Ionomers 211

        6.5.1 Influence of Heat Treatment and Cross-Linking 212

        6.5.2 Behavior of Composites 214

        6.5.3 Conclusions 215

        6.6 Dynamic Mechanical Analysis (DMA) of Polymers 217

        6.6.1 Principle of Measurement 217

        6.6.2 Molecular Motions and Dynamic Mechanical Properties 218

        6.6.3 Experimental Considerations: How Does the Instrument Work? 219

        6.6.4 Parameters of Dynamic Mechanical Analysis 220

        6.7 The DMA of Proton-Conducting Ionomers 222

        6.7.1 Perfluorosulfonic Acid Ionomer Membranes 222

        6.7.2 Nonfluorinated Membranes 225

        6.7.3 Organic–Inorganic Composite (or Hybrid) Membranes 230

        Glossary 235

        References 236

        7 Ab Initio Modeling of Transport and Structure of Solid State Proton Conductors 241
        Jeffrey K. Clark II and Stephen J. Paddison

        7.1 Introduction 241

        7.2 Theoretical Methods 244

        7.2.1 Ab Initio Electronic Structure 244

        7.2.2 Ab Initio Molecular Dynamics (AIMD) 248

        7.2.3 Empirical Valence Bond (EVB) Models 249

        7.3 Polymer Electrolyte Membranes 251

        7.3.1 Local Microstructure 251

        7.3.2 Proton Dissociation, Transfer, and Separation 258

        7.4 Crystalline Proton Conductors and Oxides 279

        7.4.1 Crystalline Proton Conductors 279

        7.4.2 Oxides 284

        7.5 Concluding Remarks 290

        References 290

        8 Perfluorinated Sulfonic Acids as Proton Conductor Membranes 295
        Giulio Alberti, Riccardo Narducci and Maria Luisa Di Vona

        8.1 Introduction on Polymer Electrolyte Membranes for Fuel Cells 295

        8.2 General Properties of Polymer Electrolyte Membranes 296

        8.2.1 Ion Exchange of Polymers Electrolytes in H þ Form 297

        8.3 Perfluorinated Membranes Containing Superacid –SO3H Groups 303

        8.3.1 Nafion Preparation 304

        8.3.2 Nafion Morphology 304

        8.3.3 Nafion Water Uptake in Liquid Water at Different Temperatures 306

        8.3.4 Water-Vapor Sorption Isotherms of Nafion 307

        8.3.5 Curves T/nc for Nafion 117 Membranes in H þ Form 308

        8.3.6 Water Uptake and Tensile Modulus of Nafion 311

        8.3.7 Colligative Properties of Inner Proton Solutions in Nafion 313

        8.3.8 Thermal Annealing of Nafion 315

        8.3.9 MCPI Method 315

        8.3.10 Proton Conductivity of Nafion 319

        8.4 Some Information on Dow and on Recent AquivionIonomers 321

        8.5 Instability of Proton Conductivity of Highly Hydrated PFSA Membranes 321

        8.6 Composite Nafion Membranes 323

        8.6.1 Silica-Filled Ionomer Membranes 323

        8.6.2 Metal Oxide-Filled Nafion Membranes 324

        8.6.3 Layered Zirconium Phosphate- and Zirconium Phosphonate-Filled Ionomer Membranes 324

        8.6.4 Heteropolyacid-Filled Membranes 325

        8.7 Some Final Remarks and Conclusions 326

        References 327

        9 Proton Conductivity of Aromatic Polymers 331
        Baijun Liu and Michael D. Guiver

        9.1 Introduction 331

        9.2 Synthetic Strategies of the Various Acid-Functionalized Aromatic Polymers with Proton Transport Ability 332

        9.2.1 Sulfonated Poly(arylene ether)s 332

        9.2.2 Sulfonated Polyimides 341

        9.2.3 Other Aromatic Polymers as PEMs 344

        9.3 Approaches to Enhance Proton Conductivity 349

        9.3.1 Nanophase-Separated Microstructures Containing Proton-Conducting Channels 349

        9.3.2 Replacement of –Ph-SO3H by –CF2 –SO3H 353

        9.3.3 Synthesis of High-IEC PEMs 355

        9.3.4 Composite Membranes 356

        9.4 Balancing Proton Conductivity, Dimensional Stability, and Other Properties 358

        9.5 Electrochemical Performance of Aromatic Polymers 361

        9.5.1 PEMFC Performance 362

        9.5.2 DMFC Performance 363

        9.6 Summary 363

        References 365

        10 Inorganic Solid Proton Conductors 371
        Philippe Knauth and Maria Luisa Di Vona

        10.1 Fundamentals of Ionic Conduction in Inorganic Solids 371

        10.1.1 Defect Concentrations 372

        10.1.2 Defect Mobilities 373

        10.1.3 Kr€oger–Vink Nomenclature 373

        10.1.4 Ionic Conduction in the Bulk: Hopping Model 376

        10.2 General Considerations on Inorganic Solid Proton Conductors 378

        10.2.1 Classification of Solid Proton Conductors 379

        10.3 Low-Dimensional Solid Proton Conductors: Layered and Porous Structures 381

        10.3.1 b- and b00-Alumina-Type 381

        10.3.2 Layered Metal Hydrogen Phosphates 382

        10.3.3 Micro- and Mesoporous Structures 384

        10.4 Three-Dimensional Solid Proton Conductors: “Quasi-Liquid” Structures 385

        10.4.1 Solid Acids 385

        10.4.2 Acid Salts 385

        10.4.3 Amorphous and Gelled Oxides and Hydroxides 387

        10.5 Three-Dimensional Solid Proton Conductors: Defect Mechanisms in Oxides 387

        10.5.1 Perovskite-Type Oxides 388

        10.5.2 Other Structure Types 393

        10.6 Conclusion 394

        References 395

        Index 399

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