Description

Book Synopsis

An interdisciplinary guide to the newest solar cell technology for efficient renewable energy

Rational Design of Solar Cells for Efficient Solar Energy Conversion explores the development of the most recent solar technology and materials used to manufacture solar cells in order to achieve higher solar energy conversion efficiency. The text offers an interdisciplinary approach and combines information on dye-sensitized solar cells, organic solar cells, polymer solar cells, perovskite solar cells, and quantum dot solar cells.

The text contains contributions from noted experts in the fields of chemistry, physics, materials science, and engineering.The authors review the development of components such as photoanodes, sensitizers, electrolytes, and photocathodes for high performance dye-sensitized solar cells. In addition, the text puts the focus on the design of material assemblies to achieve higher solar energy conversion. This important resource:

    <

    Table of Contents

    Biographies xiii

    List of Contributors xv

    Preface xix

    1 Metal Nanoparticle Decorated ZnO Nanostructure Based Dye‐Sensitized Solar Cells 1
    Gregory Thien Soon How, Kandasamy Jothivenkatachalam, Alagarsamy Pandikumar, and Nay Ming Huang

    1.1 Introduction 1

    1.2 Metal Dressed ZnO Nanostructures as Photoanodes 3

    1.2.1 Metal Dressed ZnO Nanoparticles as Photoanodes 4

    1.2.2 Metal Dressed ZnO Nanorods as Photoanodes 6

    1.2.3 Metal Dressed ZnO Nanoflowers as Photoanodes 8

    1.2.4 Metal Dressed ZnO Nanowires as Photoanodes 8

    1.2.5 Less Common Metal Dressed ZnO Nanostructures as Photoanodes 10

    1.2.6 Comparison of the Performance of Metal Dressed ZnO Nanostructures in DSSCs 10

    1.3 Conclusions and Outlook 11

    References 13

    2 Cosensitization Strategies for Dye‐Sensitized Solar Cells 15
    Gachumale Saritha, Sambandam Anandan, and Muthupandian Ashokkumar

    2.1 Introduction 15

    2.2 Cosensitization 18

    2.2.1 Cosensitization of Metal Complexes with Organic Dyes 19

    2.2.1.1 Phthalocyanine‐based Metal Complexes 19

    2.2.1.2 Porphyrin‐based Metal Complexes 21

    2.2.1.3 Ruthenium‐based Metal Complexes 27

    2.2.2 Cosensitization of Organic–Organic Dyes 41

    2.3 Conclusions 51

    Acknowledgements 51

    References 52

    3 Natural Dye‐Sensitized Solar Cells – Strategies and Measures 61
    N. Prabavathy, R. Balasundaraprabhu, and Dhayalan Velauthapillai

    3.1 Introduction 61

    3.1.1 Mechanism of the Dye‐Sensitized Solar Cell Compared with the Z‐scheme of Photosynthesis 62

    3.2 Components of Dye‐sensitized Solar Cell 63

    3.2.1 Photoelectrode 63

    3.2.2 Dye 64

    3.2.3 Liquid Electrolyte 64

    3.2.4 Counterelectrode 65

    3.3 Fabrication of Natural DSSCs 65

    3.3.1 Preparation of TiO2 Nanorods by the Hydrothermal Method 65

    3.3.2 Characterization of the Photoelectrode for DSSCs 66

    3.3.3 Preparation of Natural Dye 67

    3.3.4 Sensitization 68

    3.3.5 Arrangement of the DSSC 68

    3.4 Efficiency and Stability Enhancement in Natural Dye‐Sensitized Solar Cells 68

    3.4.1 Effect of Photocatalytic Activity of TiO2 Molecules on the Photostability of Natural Dyes 69

    3.4.1.1 Important Points to be Considered for the Preparation of Photoelectrodes 70

    3.4.2 Citric Acid – Best Solvent for Extracting Anthocyanins 70

    3.4.3. Algal Buffer Layer to Improve Stability of Anthocyanins in DSSCs 72

    3.4.3.1 Preparation of Buffer Layers – Sodium Alginate and Spirulina 73

    3.4.4 Sodium‐doped Nanorods for Enhancing the Natural DSSC Performance 75

    3.4.4.1 Preparing Sodium‐doped Nanorods as the Photoelectrode 75

    3.4.5 Absorber Material for Liquid Electrolytes to Avoid Leakage 77

    3.5 Other Strategies and Measures taken in DSSCs Using Natural Dyes 79

    3.6 Conclusions 82

    References 82

    4 Advantages of Polymer Electrolytes for Dye‐Sensitized Solar Cells 85
    L.P. Teo and A.K. Arof

    4.1 Why Solar Cells? 85

    4.2 Structure and Working Principle of DSSCs with Gel Polymer Electrolytes (GPEs) 86

    4.3 Gel Polymer Electrolytes (GPEs) 87

    4.3.1 Chitosan (Ch) and Blends 88

    4.3.2 Phthaloylchitosan (PhCh) and Blends 91

    4.3.3 Poly(Vinyl Alcohol) (PVA) 98

    4.3.4 Polyacrylonitrile (PAN) 105

    4.3.5 Polyvinylidene Fluoride (PVdF) 109

    4.4 Summary and Outlook 110

    Acknowledgements 111

    References 111

    5 Advantages of Polymer Electrolytes Towards Dye‐sensitized Solar Cells 121
    Nagaraj Pavithra, Giovanni Landi, Andrea Sorrentino, and Sambandam Anandan

    5.1 Introduction 121

    5.1.1 Energy Demand 121

    5.1.1.1 Generation of Solar Cells 122

    5.1.2 Types of Electrolyte Used in Third Generation Solar Cells 124

    5.1.2.1 Liquid Electrolytes (LEs) 124

    5.1.2.2 Room Temperature Ionic Liquids (RTILs) 125

    5.1.2.3 Solid State Hole Transport Materials (SS‐HTMs) 126

    5.2 Polymer Electrolytes 127

    5.2.1 Mechanism of Ion Transport in Polymer Electrolytes 128

    5.2.2 Types of Polymer Electrolyte 129

    5.2.2.1 Solid Polymer Electrolytes 129

    5.2.2.2 Gel Polymer Electrolytes 129

    5.2.2.3 Composite Polymer Electrolyte 130

    5.3 Dye‐ sensitized Solar Cells 130

    5.3.1 Components and Operational Principle 131

    5.3.1.1 Substrate 133

    5.3.1.2 Photoelectrode 134

    5.3.1.3 Photosensitizer 135

    5.3.1.4 Redox Electrolyte 137

    5.3.1.5 Counter Electrode 140

    5.3.2 Application of Polymer Electrolytes in DSSCs 140

    5.3.2.1 Solid‐state Dye-Sensitized Solar Cells (SS‐DSSCs) 140

    5.3.2.2 Quasi‐solid‐state Dye-Sensitized Solar Cells (QS‐DSSC) 142

    5.3.2.3 Types of Additives in GPEs 144

    5.3.3 Bifacial DSSCs 148

    5.4 Quantum Dot Sensitized Solar Cells (QDSSC) 150

    5.5 Perovskite‐ Sensitized Solar Cells (PSSC) 152

    5.6 Conclusion 153

    Acknowledgements 154

    References 154

    6 Rational Screening Strategies for Counter Electrode Nanocomposite Materials for Efficient Solar Energy Conversion 169
    Prabhakarn Arunachalam

    6.1 Introduction 169

    6.2 Principles of Next Generation Solar Cells 171

    6.2.1 Dye‐sensitized Solar Cells 171

    6.2.2 Principles of Quantum Dot Sensitized Solar Cells 173

    6.2.3 Principles of Perovskite Solar Cells 174

    6.3 Platinum‐ free Counterelectrode Materials 175

    6.3.1 Carbon‐based Materials for Solar Energy Conversion 175

    6.3.2 Metal Nitride and Carbide Materials 178

    6.3.3 Metal Sulfide Materials 179

    6.3.4 Composite Materials 182

    6.3.5 Metal Oxide Materials 183

    6.3.6 Polymer Counterelectrodes 184

    6.4 Summary and Outlook 185

    References 186

    7 Design and Fabrication of Carbon‐based Nanostructured Counter Electrode Materials for Dye‐sensitized Solar Cells 193
    Jayaraman Theerthagiri, Raja Arumugam Senthil, and Jagannathan Madhavan

    7.1 Photovoltaic Solar Cells – An Overview 193

    7.1.1 First Generation Solar Cells 194

    7.1.2 Second Generation Solar Cells 194

    7.1.3 Third Generation Solar Cells 194

    7.1.4 Fourth Generation Solar Cells 195

    7.2 Dye‐ sensitized Solar Cells 195

    7.2.1 Major Components of DSSCs 196

    7.2.1.1 Transparent Conducting Glass Substrate 197

    7.2.1.2 Photoelectrode 197

    7.2.1.3 Dye Sensitizer 198

    7.2.1.4 Redox Electrolytes 199

    7.2.1.5 Counterelectrode 200

    7.2.2 Working Mechanism of DSSCs 200

    7.3 Carbon‐ based Nanostructured CE Materials for DSSCs 201

    7.4 Conclusions 216

    References 217

    8 Highly Stable Inverted Organic Solar Cells Based on Novel Interfacial Layers 221
    Fang Jeng Lim and Ananthanarayanan Krishnamoorthy

    8.1 Introduction 221

    8.2 Research Areas in Organic Solar Cells 222

    8.3 An Overview of Inverted Organic Solar Cells 224

    8.3.1 Transport Layers in Inverted Organic Solar Cells 227

    8.3.2 PEDOT:PSS Hole Transport Layer 227

    8.3.3 Titanium Oxide Electron Transport Layer 229

    8.4 Issues in Inverted Organic Solar Cells and Respective Solutions 232

    8.4.1 Wettability Issue of PEDOT:PSS in Inverted Organic Solar Cells 233

    8.4.2 Light‐soaking Issue of TiOx‐based Inverted Organic Solar Cells 234

    8.5 Overcoming the Wettability Issue and Light‐soaking Issue in Inverted Organic Solar Cells 235

    8.5.1 Fluorosurfactant‐modified PEDOT:PSS as Hole Transport Layer 235

    8.5.2 Fluorinated Titanium Oxide as Electron Transport Layer 239

    8.6 Conclusions and Outlook 245

    Acknowledgements 246

    References 246

    9 Fabrication of Metal Top Electrode via Solution‐based Printing Technique for Efficient Inverted Organic Solar Cells 255
    Navaneethan Duraisamy, Kavitha Kandiah, Kyung‐Hyun Choi, Dhanaraj Gopi, Ramesh Rajendran, Pazhanivel Thangavelu, and Maadeswaran Palanisamy

    9.1 Introduction 255

    9.2 Organic Photovoltaic Cells 257

    9.3 Working Principle 258

    9.4 Device Architecture 260

    9.4.1 Single Layer or Monolayer Device 260

    9.4.2 Planar Heterojunction Device 261

    9.4.3 Bulk Heterojunction Device 261

    9.4.4 Ordered Bulk Heterojunction Device 261

    9.4.5 Inverted Organic Solar Cells 262

    9.5 Fabrication Process 263

    9.5.1 Hybrid‐EHDA Technique 263

    9.5.1.1 Flow Rate 265

    9.5.1.2 Applied Potential 265

    9.5.1.3 Pneumatic Pressure 265

    9.5.1.4 Stand‐off Distance 265

    9.5.1.5 Nozzle Diameter 266

    9.5.1.6 Ink Properties 266

    9.5.2 Mode of Atomization 267

    9.5.2.1 Dripping Mode 267

    9.5.2.2 Unstable Spray Mode 267

    9.5.2.3 Stable Spray Mode 267

    9.6 Fabrication of Inverted Organic Solar Cells 267

    9.6.1 Deposition of Zinc Oxide (ZnO) on ITO Substrate 268

    9.6.2 Deposition of P3HT:PCBM 268

    9.6.3 Deposition of PEDOT:PSS 268

    9.6.4 Deposition of Silver as a Top Electrode 269

    9.7 Device Morphology 272

    9.8 Device Performance 273

    9.9 Conclusion 277

    Acknowledgements 277

    References 277

    10 Polymer Solar Cells – An Energy Technology for the Future 283

    Alagar Ramar and Fu‐Ming Wang

    10.1 Introduction 283

    10.2 Materials Developments for Bulk Heterojunction Solar Cells 284

    10.2.1 Conjugated Polymer–Fullerene Solar Cells 284

    10.2.2 Non‐Fullerene Polymer Solar Cells 289

    10.2.3 All‐Polymer Solar Cells 290

    10.3 Materials Developments for Molecular Heterojunction Solar Cells 291

    10.3.1 Double‐cable Polymers 291

    10.4 Developments in Device Structures 293

    10.4.1 Tandem Solar Cells 295

    10.4.2 Inverted Polymer Solar Cells 297

    10.5 Conclusions 300

    Acknowledgements 300

    References 301

    11 Rational Strategies for Large‐area Perovskite Solar Cells: Laboratory Scale to Industrial Technology 307
    Arunachalam Arulraj and Mohan Ramesh

    11.1 Introduction 307

    11.2 Perovskite 308

    11.3 Perovskite Solar Cells 309

    11.3.1 Architecture 310

    11.3.1.1 Mesoporous PSCs 310

    11.3.1.2 Planar PSCs 313

    11.4 Device Processing 313

    11.4.1 Solvent Engineering 313

    11.4.2 Compositional Engineering 314

    11.4.3 Interfacial Engineering 314

    11.5 Enhancing the Stability of Devices 316

    11.5.1 Deposition Techniques 317

    11.5.1.1 Spin Coating 317

    11.5.1.2 Blade Coating 319

    11.5.1.3 Slot Die Coating 320

    11.5.1.4 Screen Printing 321

    11.5.1.5 Spray Coating 324

    11.5.1.6 Laser Patterning 324

    11.5.1.7 Roll‐to‐Roll Deposition 325

    11.5.1.8 Other Large Area Deposition Techniques 326

    11.6 Summary 329

    Acknowledgement 329

    References 329

    12 Hot Electrons Role in Biomolecule‐based Quantum Dot Hybrid Solar Cells 339
    T. Pazhanivel, G. Bharathi, D. Nataraj, R. Ramesh, and D. Navaneethan

    12.1 Introduction 339

    12.2 Classifications of Solar Cells 341

    12.2.1 Inorganic Solar Cells 342

    12.2.2 Organic Solar Cells (OSCs) 343

    12.2.3 Hybrid Solar Cells 344

    12.3 Main Losses in Solar Cells 344

    12.3.1 Recombination Loss 345

    12.3.2 Contact Losses 345

    12.4 Hot Electron Concept in Materials 346

    12.5 Methodology 347

    12.5.1 Hot Injection Method 348

    12.5.1.1 Nucleation and Growth Stages 349

    12.5.1.2 Merits of this Method 350

    12.6 Material Synthesis 350

    12.6.1 CdSe QD Preparation 350

    12.6.2 QD–βC Hybrid Formation 351

    12.7 Identification of Hot Electrons 351

    12.7.1 Photoluminescence (PL) Spectrum 351

    12.7.2 Time‐correlated Single Photon Counting (TCSPC) 355

    12.7.3 Transient Absorption 357

    12.8 Quantum Dot Sensitized Solar Cells 360

    12.8.1 Working Principle 360

    12.8.2 Device Preparation 361

    12.8.2.1 Preparation of TiO2 Nanoparticle Electrode 361

    12.8.2.2 QDs Deposition on TiO2 Nanoparticle 362

    12.8.2.3 Counterelectrode and Assembly of QDSSC 362

    12.8.3 Performance 362

    12.9 Conclusion 363

    References 363

    Index 369

Rational Design of Solar Cells for Efficient

    Product form

    £146.66

    Includes FREE delivery

    RRP £162.95 – you save £16.29 (9%)

    Order before 4pm today for delivery by Sat 4 Jul 2026.

    A Hardback by Alagarsamy Pandikumar, Ramasamy Ramaraj

    3 in stock

      Trusted by thousands of customers. See 2,385+ Customer Reviews

      View other formats and editions of Rational Design of Solar Cells for Efficient by Alagarsamy Pandikumar

      Publisher: John Wiley & Sons Inc
      Publication Date: 30/11/2018
      ISBN13: 9781119437406, 978-1119437406
      ISBN10: 1119437407
      Also in:
      Mechanical engineering and materials

      Description

      Book Synopsis

      An interdisciplinary guide to the newest solar cell technology for efficient renewable energy

      Rational Design of Solar Cells for Efficient Solar Energy Conversion explores the development of the most recent solar technology and materials used to manufacture solar cells in order to achieve higher solar energy conversion efficiency. The text offers an interdisciplinary approach and combines information on dye-sensitized solar cells, organic solar cells, polymer solar cells, perovskite solar cells, and quantum dot solar cells.

      The text contains contributions from noted experts in the fields of chemistry, physics, materials science, and engineering.The authors review the development of components such as photoanodes, sensitizers, electrolytes, and photocathodes for high performance dye-sensitized solar cells. In addition, the text puts the focus on the design of material assemblies to achieve higher solar energy conversion. This important resource:

        <

        Table of Contents

        Biographies xiii

        List of Contributors xv

        Preface xix

        1 Metal Nanoparticle Decorated ZnO Nanostructure Based Dye‐Sensitized Solar Cells 1
        Gregory Thien Soon How, Kandasamy Jothivenkatachalam, Alagarsamy Pandikumar, and Nay Ming Huang

        1.1 Introduction 1

        1.2 Metal Dressed ZnO Nanostructures as Photoanodes 3

        1.2.1 Metal Dressed ZnO Nanoparticles as Photoanodes 4

        1.2.2 Metal Dressed ZnO Nanorods as Photoanodes 6

        1.2.3 Metal Dressed ZnO Nanoflowers as Photoanodes 8

        1.2.4 Metal Dressed ZnO Nanowires as Photoanodes 8

        1.2.5 Less Common Metal Dressed ZnO Nanostructures as Photoanodes 10

        1.2.6 Comparison of the Performance of Metal Dressed ZnO Nanostructures in DSSCs 10

        1.3 Conclusions and Outlook 11

        References 13

        2 Cosensitization Strategies for Dye‐Sensitized Solar Cells 15
        Gachumale Saritha, Sambandam Anandan, and Muthupandian Ashokkumar

        2.1 Introduction 15

        2.2 Cosensitization 18

        2.2.1 Cosensitization of Metal Complexes with Organic Dyes 19

        2.2.1.1 Phthalocyanine‐based Metal Complexes 19

        2.2.1.2 Porphyrin‐based Metal Complexes 21

        2.2.1.3 Ruthenium‐based Metal Complexes 27

        2.2.2 Cosensitization of Organic–Organic Dyes 41

        2.3 Conclusions 51

        Acknowledgements 51

        References 52

        3 Natural Dye‐Sensitized Solar Cells – Strategies and Measures 61
        N. Prabavathy, R. Balasundaraprabhu, and Dhayalan Velauthapillai

        3.1 Introduction 61

        3.1.1 Mechanism of the Dye‐Sensitized Solar Cell Compared with the Z‐scheme of Photosynthesis 62

        3.2 Components of Dye‐sensitized Solar Cell 63

        3.2.1 Photoelectrode 63

        3.2.2 Dye 64

        3.2.3 Liquid Electrolyte 64

        3.2.4 Counterelectrode 65

        3.3 Fabrication of Natural DSSCs 65

        3.3.1 Preparation of TiO2 Nanorods by the Hydrothermal Method 65

        3.3.2 Characterization of the Photoelectrode for DSSCs 66

        3.3.3 Preparation of Natural Dye 67

        3.3.4 Sensitization 68

        3.3.5 Arrangement of the DSSC 68

        3.4 Efficiency and Stability Enhancement in Natural Dye‐Sensitized Solar Cells 68

        3.4.1 Effect of Photocatalytic Activity of TiO2 Molecules on the Photostability of Natural Dyes 69

        3.4.1.1 Important Points to be Considered for the Preparation of Photoelectrodes 70

        3.4.2 Citric Acid – Best Solvent for Extracting Anthocyanins 70

        3.4.3. Algal Buffer Layer to Improve Stability of Anthocyanins in DSSCs 72

        3.4.3.1 Preparation of Buffer Layers – Sodium Alginate and Spirulina 73

        3.4.4 Sodium‐doped Nanorods for Enhancing the Natural DSSC Performance 75

        3.4.4.1 Preparing Sodium‐doped Nanorods as the Photoelectrode 75

        3.4.5 Absorber Material for Liquid Electrolytes to Avoid Leakage 77

        3.5 Other Strategies and Measures taken in DSSCs Using Natural Dyes 79

        3.6 Conclusions 82

        References 82

        4 Advantages of Polymer Electrolytes for Dye‐Sensitized Solar Cells 85
        L.P. Teo and A.K. Arof

        4.1 Why Solar Cells? 85

        4.2 Structure and Working Principle of DSSCs with Gel Polymer Electrolytes (GPEs) 86

        4.3 Gel Polymer Electrolytes (GPEs) 87

        4.3.1 Chitosan (Ch) and Blends 88

        4.3.2 Phthaloylchitosan (PhCh) and Blends 91

        4.3.3 Poly(Vinyl Alcohol) (PVA) 98

        4.3.4 Polyacrylonitrile (PAN) 105

        4.3.5 Polyvinylidene Fluoride (PVdF) 109

        4.4 Summary and Outlook 110

        Acknowledgements 111

        References 111

        5 Advantages of Polymer Electrolytes Towards Dye‐sensitized Solar Cells 121
        Nagaraj Pavithra, Giovanni Landi, Andrea Sorrentino, and Sambandam Anandan

        5.1 Introduction 121

        5.1.1 Energy Demand 121

        5.1.1.1 Generation of Solar Cells 122

        5.1.2 Types of Electrolyte Used in Third Generation Solar Cells 124

        5.1.2.1 Liquid Electrolytes (LEs) 124

        5.1.2.2 Room Temperature Ionic Liquids (RTILs) 125

        5.1.2.3 Solid State Hole Transport Materials (SS‐HTMs) 126

        5.2 Polymer Electrolytes 127

        5.2.1 Mechanism of Ion Transport in Polymer Electrolytes 128

        5.2.2 Types of Polymer Electrolyte 129

        5.2.2.1 Solid Polymer Electrolytes 129

        5.2.2.2 Gel Polymer Electrolytes 129

        5.2.2.3 Composite Polymer Electrolyte 130

        5.3 Dye‐ sensitized Solar Cells 130

        5.3.1 Components and Operational Principle 131

        5.3.1.1 Substrate 133

        5.3.1.2 Photoelectrode 134

        5.3.1.3 Photosensitizer 135

        5.3.1.4 Redox Electrolyte 137

        5.3.1.5 Counter Electrode 140

        5.3.2 Application of Polymer Electrolytes in DSSCs 140

        5.3.2.1 Solid‐state Dye-Sensitized Solar Cells (SS‐DSSCs) 140

        5.3.2.2 Quasi‐solid‐state Dye-Sensitized Solar Cells (QS‐DSSC) 142

        5.3.2.3 Types of Additives in GPEs 144

        5.3.3 Bifacial DSSCs 148

        5.4 Quantum Dot Sensitized Solar Cells (QDSSC) 150

        5.5 Perovskite‐ Sensitized Solar Cells (PSSC) 152

        5.6 Conclusion 153

        Acknowledgements 154

        References 154

        6 Rational Screening Strategies for Counter Electrode Nanocomposite Materials for Efficient Solar Energy Conversion 169
        Prabhakarn Arunachalam

        6.1 Introduction 169

        6.2 Principles of Next Generation Solar Cells 171

        6.2.1 Dye‐sensitized Solar Cells 171

        6.2.2 Principles of Quantum Dot Sensitized Solar Cells 173

        6.2.3 Principles of Perovskite Solar Cells 174

        6.3 Platinum‐ free Counterelectrode Materials 175

        6.3.1 Carbon‐based Materials for Solar Energy Conversion 175

        6.3.2 Metal Nitride and Carbide Materials 178

        6.3.3 Metal Sulfide Materials 179

        6.3.4 Composite Materials 182

        6.3.5 Metal Oxide Materials 183

        6.3.6 Polymer Counterelectrodes 184

        6.4 Summary and Outlook 185

        References 186

        7 Design and Fabrication of Carbon‐based Nanostructured Counter Electrode Materials for Dye‐sensitized Solar Cells 193
        Jayaraman Theerthagiri, Raja Arumugam Senthil, and Jagannathan Madhavan

        7.1 Photovoltaic Solar Cells – An Overview 193

        7.1.1 First Generation Solar Cells 194

        7.1.2 Second Generation Solar Cells 194

        7.1.3 Third Generation Solar Cells 194

        7.1.4 Fourth Generation Solar Cells 195

        7.2 Dye‐ sensitized Solar Cells 195

        7.2.1 Major Components of DSSCs 196

        7.2.1.1 Transparent Conducting Glass Substrate 197

        7.2.1.2 Photoelectrode 197

        7.2.1.3 Dye Sensitizer 198

        7.2.1.4 Redox Electrolytes 199

        7.2.1.5 Counterelectrode 200

        7.2.2 Working Mechanism of DSSCs 200

        7.3 Carbon‐ based Nanostructured CE Materials for DSSCs 201

        7.4 Conclusions 216

        References 217

        8 Highly Stable Inverted Organic Solar Cells Based on Novel Interfacial Layers 221
        Fang Jeng Lim and Ananthanarayanan Krishnamoorthy

        8.1 Introduction 221

        8.2 Research Areas in Organic Solar Cells 222

        8.3 An Overview of Inverted Organic Solar Cells 224

        8.3.1 Transport Layers in Inverted Organic Solar Cells 227

        8.3.2 PEDOT:PSS Hole Transport Layer 227

        8.3.3 Titanium Oxide Electron Transport Layer 229

        8.4 Issues in Inverted Organic Solar Cells and Respective Solutions 232

        8.4.1 Wettability Issue of PEDOT:PSS in Inverted Organic Solar Cells 233

        8.4.2 Light‐soaking Issue of TiOx‐based Inverted Organic Solar Cells 234

        8.5 Overcoming the Wettability Issue and Light‐soaking Issue in Inverted Organic Solar Cells 235

        8.5.1 Fluorosurfactant‐modified PEDOT:PSS as Hole Transport Layer 235

        8.5.2 Fluorinated Titanium Oxide as Electron Transport Layer 239

        8.6 Conclusions and Outlook 245

        Acknowledgements 246

        References 246

        9 Fabrication of Metal Top Electrode via Solution‐based Printing Technique for Efficient Inverted Organic Solar Cells 255
        Navaneethan Duraisamy, Kavitha Kandiah, Kyung‐Hyun Choi, Dhanaraj Gopi, Ramesh Rajendran, Pazhanivel Thangavelu, and Maadeswaran Palanisamy

        9.1 Introduction 255

        9.2 Organic Photovoltaic Cells 257

        9.3 Working Principle 258

        9.4 Device Architecture 260

        9.4.1 Single Layer or Monolayer Device 260

        9.4.2 Planar Heterojunction Device 261

        9.4.3 Bulk Heterojunction Device 261

        9.4.4 Ordered Bulk Heterojunction Device 261

        9.4.5 Inverted Organic Solar Cells 262

        9.5 Fabrication Process 263

        9.5.1 Hybrid‐EHDA Technique 263

        9.5.1.1 Flow Rate 265

        9.5.1.2 Applied Potential 265

        9.5.1.3 Pneumatic Pressure 265

        9.5.1.4 Stand‐off Distance 265

        9.5.1.5 Nozzle Diameter 266

        9.5.1.6 Ink Properties 266

        9.5.2 Mode of Atomization 267

        9.5.2.1 Dripping Mode 267

        9.5.2.2 Unstable Spray Mode 267

        9.5.2.3 Stable Spray Mode 267

        9.6 Fabrication of Inverted Organic Solar Cells 267

        9.6.1 Deposition of Zinc Oxide (ZnO) on ITO Substrate 268

        9.6.2 Deposition of P3HT:PCBM 268

        9.6.3 Deposition of PEDOT:PSS 268

        9.6.4 Deposition of Silver as a Top Electrode 269

        9.7 Device Morphology 272

        9.8 Device Performance 273

        9.9 Conclusion 277

        Acknowledgements 277

        References 277

        10 Polymer Solar Cells – An Energy Technology for the Future 283

        Alagar Ramar and Fu‐Ming Wang

        10.1 Introduction 283

        10.2 Materials Developments for Bulk Heterojunction Solar Cells 284

        10.2.1 Conjugated Polymer–Fullerene Solar Cells 284

        10.2.2 Non‐Fullerene Polymer Solar Cells 289

        10.2.3 All‐Polymer Solar Cells 290

        10.3 Materials Developments for Molecular Heterojunction Solar Cells 291

        10.3.1 Double‐cable Polymers 291

        10.4 Developments in Device Structures 293

        10.4.1 Tandem Solar Cells 295

        10.4.2 Inverted Polymer Solar Cells 297

        10.5 Conclusions 300

        Acknowledgements 300

        References 301

        11 Rational Strategies for Large‐area Perovskite Solar Cells: Laboratory Scale to Industrial Technology 307
        Arunachalam Arulraj and Mohan Ramesh

        11.1 Introduction 307

        11.2 Perovskite 308

        11.3 Perovskite Solar Cells 309

        11.3.1 Architecture 310

        11.3.1.1 Mesoporous PSCs 310

        11.3.1.2 Planar PSCs 313

        11.4 Device Processing 313

        11.4.1 Solvent Engineering 313

        11.4.2 Compositional Engineering 314

        11.4.3 Interfacial Engineering 314

        11.5 Enhancing the Stability of Devices 316

        11.5.1 Deposition Techniques 317

        11.5.1.1 Spin Coating 317

        11.5.1.2 Blade Coating 319

        11.5.1.3 Slot Die Coating 320

        11.5.1.4 Screen Printing 321

        11.5.1.5 Spray Coating 324

        11.5.1.6 Laser Patterning 324

        11.5.1.7 Roll‐to‐Roll Deposition 325

        11.5.1.8 Other Large Area Deposition Techniques 326

        11.6 Summary 329

        Acknowledgement 329

        References 329

        12 Hot Electrons Role in Biomolecule‐based Quantum Dot Hybrid Solar Cells 339
        T. Pazhanivel, G. Bharathi, D. Nataraj, R. Ramesh, and D. Navaneethan

        12.1 Introduction 339

        12.2 Classifications of Solar Cells 341

        12.2.1 Inorganic Solar Cells 342

        12.2.2 Organic Solar Cells (OSCs) 343

        12.2.3 Hybrid Solar Cells 344

        12.3 Main Losses in Solar Cells 344

        12.3.1 Recombination Loss 345

        12.3.2 Contact Losses 345

        12.4 Hot Electron Concept in Materials 346

        12.5 Methodology 347

        12.5.1 Hot Injection Method 348

        12.5.1.1 Nucleation and Growth Stages 349

        12.5.1.2 Merits of this Method 350

        12.6 Material Synthesis 350

        12.6.1 CdSe QD Preparation 350

        12.6.2 QD–βC Hybrid Formation 351

        12.7 Identification of Hot Electrons 351

        12.7.1 Photoluminescence (PL) Spectrum 351

        12.7.2 Time‐correlated Single Photon Counting (TCSPC) 355

        12.7.3 Transient Absorption 357

        12.8 Quantum Dot Sensitized Solar Cells 360

        12.8.1 Working Principle 360

        12.8.2 Device Preparation 361

        12.8.2.1 Preparation of TiO2 Nanoparticle Electrode 361

        12.8.2.2 QDs Deposition on TiO2 Nanoparticle 362

        12.8.2.3 Counterelectrode and Assembly of QDSSC 362

        12.8.3 Performance 362

        12.9 Conclusion 363

        References 363

        Index 369

      Recently viewed products

      © 2026 Book Curl

        • American Express
        • Apple Pay
        • Diners Club
        • Discover
        • Google Pay
        • Maestro
        • Mastercard
        • PayPal
        • Shop Pay
        • Union Pay
        • Visa

        Login

        Forgot your password?

        Don't have an account yet?
        Create account