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Organic and Hybrid Solar Cells
This chapter is in the book Organic and Hybrid Solar Cells
Indexβ-carotene, 39π-electrons, 35ππstacking, 166Rsh, 111FF, 111JSC, 111PCE, 111Pmax, 107Rs, 111VOC, 111Absorbance, 103, 231Absorber nanoparticles, 193Absorption, 48, 56, 103, 231Absorption spectroscopy, 230– Haze measurement, 247– Total absorption, 244– Transfer matrix simulations, 246Active area, 249– Current density, 250– Masking, 251AM 1.5G, 96Anderson’s rule, 89Annealing, 173Auger recombination, 258Back-contacted solar cells, 138Ball-and-stick model, 32Band bending, 82Band structure, 8, 12– Bandgap, 9– Conduction band, 8– Valence band, 8Bandgap, 9, 18– Direct bandgap, 18– Indirect bandgap, 18Base, 114BaSO4, 245Beer–Lambert’s law, 231, 236Bias-dependent charge extraction, 156Bilayer OPV, 159Bimolecular recombination, 259Black body radiation, 98Bloch wave, 16Born-Oppenheimer approximation, 50Brillouin zone, 14Built-in voltage, 83Bulk heterojunction, 161– Annealing, 173– Demixing, 173– External quantum efficiency, 163– Glass transition, 174– Internal quantum efficiency, 163– Metal oxide–polymer, 189– Phase separation, 162, 172– Polymer–fullerene mixing, 163Bässler model, 75C60– Crystallization, 169Carbon atom– Hybridization, 28– single/double/triple bond, 30Carbon orbitals, 28Carboxylic acid, 181CdSe, 193CdTe, 193Characteristics of solar cells, 105Charge carrier mobility, 11, 75, 77, 79, 125, 127,166–168, 215, 239, 259, 269– FET mobility, 127, 129, 130Charge diffusion, 78Charge extraction probability, 261Charge generation– Charge separated state, 147– Charge transfer state, 147– Excess energy, 156– Exciton splitting, 146– Organic solar cell, 146Charge hopping, 68Charge separated state, 148Charge separation probability, 259Charge transfer exciton, 62Charge transfer state, 147– CTS0, 152– CTSn, 153– Electroluminescence, 151– Energetics, 152– Excess energy, 156– Hot charge transfer state, 153– Pump-push spectroscopy, 153Charge transport, 67– Bässler model, 75https://doi.org/10.1515/9783110736939-012
© 2022 Walter de Gruyter GmbH, Berlin/Boston

Indexβ-carotene, 39π-electrons, 35ππstacking, 166Rsh, 111FF, 111JSC, 111PCE, 111Pmax, 107Rs, 111VOC, 111Absorbance, 103, 231Absorber nanoparticles, 193Absorption, 48, 56, 103, 231Absorption spectroscopy, 230– Haze measurement, 247– Total absorption, 244– Transfer matrix simulations, 246Active area, 249– Current density, 250– Masking, 251AM 1.5G, 96Anderson’s rule, 89Annealing, 173Auger recombination, 258Back-contacted solar cells, 138Ball-and-stick model, 32Band bending, 82Band structure, 8, 12– Bandgap, 9– Conduction band, 8– Valence band, 8Bandgap, 9, 18– Direct bandgap, 18– Indirect bandgap, 18Base, 114BaSO4, 245Beer–Lambert’s law, 231, 236Bias-dependent charge extraction, 156Bilayer OPV, 159Bimolecular recombination, 259Black body radiation, 98Bloch wave, 16Born-Oppenheimer approximation, 50Brillouin zone, 14Built-in voltage, 83Bulk heterojunction, 161– Annealing, 173– Demixing, 173– External quantum efficiency, 163– Glass transition, 174– Internal quantum efficiency, 163– Metal oxide–polymer, 189– Phase separation, 162, 172– Polymer–fullerene mixing, 163Bässler model, 75C60– Crystallization, 169Carbon atom– Hybridization, 28– single/double/triple bond, 30Carbon orbitals, 28Carboxylic acid, 181CdSe, 193CdTe, 193Characteristics of solar cells, 105Charge carrier mobility, 11, 75, 77, 79, 125, 127,166–168, 215, 239, 259, 269– FET mobility, 127, 129, 130Charge diffusion, 78Charge extraction probability, 261Charge generation– Charge separated state, 147– Charge transfer state, 147– Excess energy, 156– Exciton splitting, 146– Organic solar cell, 146Charge hopping, 68Charge separated state, 148Charge separation probability, 259Charge transfer exciton, 62Charge transfer state, 147– CTS0, 152– CTSn, 153– Electroluminescence, 151– Energetics, 152– Excess energy, 156– Hot charge transfer state, 153– Pump-push spectroscopy, 153Charge transport, 67– Bässler model, 75https://doi.org/10.1515/9783110736939-012
© 2022 Walter de Gruyter GmbH, Berlin/Boston

Chapters in this book

  1. Frontmatter I
  2. Contents V
  3. Preface IX
  4. Preface of 2nd Edition XI
  5. 1 Introduction 1
  6. 2 Semiconductors and Junctions 8
  7. 3 Working Mechanisms of Organic and Hybrid Solar Cells 96
  8. 4 Organic Solar Cells 146
  9. 5 Hybrid Junction Solar Cells 180
  10. 6 Perovskite Solar Cells 197
  11. 7 Characterization Techniques 230
  12. 8 Fabrication and Device Lifetime 284
  13. 9 Conclusion and Outlook 303
  14. 10 Questions and Exercises 304
  15. Bibliography 317
  16. Index 342
Readers are also interested in:
https://doi.org/10.1515/9783110736939-012

Chapters in this book

  1. Frontmatter I
  2. Contents V
  3. Preface IX
  4. Preface of 2nd Edition XI
  5. 1 Introduction 1
  6. 2 Semiconductors and Junctions 8
  7. 3 Working Mechanisms of Organic and Hybrid Solar Cells 96
  8. 4 Organic Solar Cells 146
  9. 5 Hybrid Junction Solar Cells 180
  10. 6 Perovskite Solar Cells 197
  11. 7 Characterization Techniques 230
  12. 8 Fabrication and Device Lifetime 284
  13. 9 Conclusion and Outlook 303
  14. 10 Questions and Exercises 304
  15. Bibliography 317
  16. Index 342
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