Organic Solar Cells

Organic Solar Cells

by Qiquan Qiao
Released December 2017
Publisher(s): CRC Press
ISBN: 9781351831215

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Book description

This comprehensive book encompasses the full spectrum of organic solar cell materials, modeling and simulation, and device physics and engineering. It discusses active layer, interfacial, and transparent electrode materials. It explains how to relate synthesis parameters to morphology of the photoactive layer using molecular dynamics simulations, as well as offers insight into coupling morphology and interfaces with charge transport in organic solar cells. It also explores photoexcited carrier dynamics, defect states, interface engineering, nanophase separation, inorganic–organic hybrids, tandem structure, and graphene-based polymer solar cells.

Table of contents

  1. Front Cover (1/2)
  2. Front Cover (2/2)
  3. Contents
  4. Preface
  5. Editors
  6. Contributors (1/2)
  7. Contributors (2/2)
  8. Chapter 1: Conjugated Polymers as Electron Donors in Organic Solar Cells (1/4)
  9. Chapter 1: Conjugated Polymers as Electron Donors in Organic Solar Cells (2/4)
  10. Chapter 1: Conjugated Polymers as Electron Donors in Organic Solar Cells (3/4)
  11. Chapter 1: Conjugated Polymers as Electron Donors in Organic Solar Cells (4/4)
  12. Chapter 2: Donor and Acceptor Functionalized Silsesquioxane Nanostructures for Organic-Based Photovoltaic Devices (1/5)
  13. Chapter 2: Donor and Acceptor Functionalized Silsesquioxane Nanostructures for Organic-Based Photovoltaic Devices (2/5)
  14. Chapter 2: Donor and Acceptor Functionalized Silsesquioxane Nanostructures for Organic-Based Photovoltaic Devices (3/5)
  15. Chapter 2: Donor and Acceptor Functionalized Silsesquioxane Nanostructures for Organic-Based Photovoltaic Devices (4/5)
  16. Chapter 2: Donor and Acceptor Functionalized Silsesquioxane Nanostructures for Organic-Based Photovoltaic Devices (5/5)
  17. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (1/10)
  18. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (2/10)
  19. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (3/10)
  20. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (4/10)
  21. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (5/10)
  22. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (6/10)
  23. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (7/10)
  24. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (8/10)
  25. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (9/10)
  26. Chapter 3: Next-Generation Transparent Electrode Materials for Organic Solar Cells (10/10)
  27. Chapter 4: Relating Synthesis Parameters to the Morphology of the Photoactive Layer in Organic Photovoltaic Solar Cells Using Molecular Dynamics Simulations (1/5)
  28. Chapter 4: Relating Synthesis Parameters to the Morphology of the Photoactive Layer in Organic Photovoltaic Solar Cells Using Molecular Dynamics Simulations (2/5)
  29. Chapter 4: Relating Synthesis Parameters to the Morphology of the Photoactive Layer in Organic Photovoltaic Solar Cells Using Molecular Dynamics Simulations (3/5)
  30. Chapter 4: Relating Synthesis Parameters to the Morphology of the Photoactive Layer in Organic Photovoltaic Solar Cells Using Molecular Dynamics Simulations (4/5)
  31. Chapter 4: Relating Synthesis Parameters to the Morphology of the Photoactive Layer in Organic Photovoltaic Solar Cells Using Molecular Dynamics Simulations (5/5)
  32. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (1/6)
  33. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (2/6)
  34. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (3/6)
  35. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (4/6)
  36. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (5/6)
  37. Chapter 5: Insights Obtained from Modeling of Organic Photovoltaics : Morphology, Interfaces, and Coupling with Charge Transport (6/6)
  38. Chapter 6: Photoexcited Carrier Dynamics in Organic Solar Cells (1/5)
  39. Chapter 6: Photoexcited Carrier Dynamics in Organic Solar Cells (2/5)
  40. Chapter 6: Photoexcited Carrier Dynamics in Organic Solar Cells (3/5)
  41. Chapter 6: Photoexcited Carrier Dynamics in Organic Solar Cells (4/5)
  42. Chapter 6: Photoexcited Carrier Dynamics in Organic Solar Cells (5/5)
  43. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (1/7)
  44. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (2/7)
  45. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (3/7)
  46. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (4/7)
  47. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (5/7)
  48. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (6/7)
  49. Chapter 7: Defect States in Organic Photovoltaic Materials, Thin Films, and Devices (7/7)
  50. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (1/10)
  51. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (2/10)
  52. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (3/10)
  53. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (4/10)
  54. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (5/10)
  55. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (6/10)
  56. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (7/10)
  57. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (8/10)
  58. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (9/10)
  59. Chapter 8: Interfacial Materials toward Efficiency Enhancement of Polymer Solar Cells (10/10)
  60. Chapter 9: Nanophase Separation in Organic Solar Cells (1/7)
  61. Chapter 9: Nanophase Separation in Organic Solar Cells (2/7)
  62. Chapter 9: Nanophase Separation in Organic Solar Cells (3/7)
  63. Chapter 9: Nanophase Separation in Organic Solar Cells (4/7)
  64. Chapter 9: Nanophase Separation in Organic Solar Cells (5/7)
  65. Chapter 9: Nanophase Separation in Organic Solar Cells (6/7)
  66. Chapter 9: Nanophase Separation in Organic Solar Cells (7/7)
  67. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (1/6)
  68. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (2/6)
  69. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (3/6)
  70. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (4/6)
  71. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (5/6)
  72. Chapter 10: Engineering of Active Layer Nanomorphology via Fullerene Ratios and Solvent Additives for Improved Charge Transport in Polymer Solar Cells (6/6)
  73. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (1/6)
  74. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (2/6)
  75. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (3/6)
  76. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (4/6)
  77. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (5/6)
  78. Chapter 11: Inorganic–Organic Nanocomposites and Their Assemblies for Solar Energy Conversion (6/6)
  79. Chapter 12: Organic Tandem Solar Cells (1/9)
  80. Chapter 12: Organic Tandem Solar Cells (2/9)
  81. Chapter 12: Organic Tandem Solar Cells (3/9)
  82. Chapter 12: Organic Tandem Solar Cells (4/9)
  83. Chapter 12: Organic Tandem Solar Cells (5/9)
  84. Chapter 12: Organic Tandem Solar Cells (6/9)
  85. Chapter 12: Organic Tandem Solar Cells (7/9)
  86. Chapter 12: Organic Tandem Solar Cells (8/9)
  87. Chapter 12: Organic Tandem Solar Cells (9/9)
  88. Chapter 13: Graphene-Based Polymer and Organic Solar Cells (1/5)
  89. Chapter 13: Graphene-Based Polymer and Organic Solar Cells (2/5)
  90. Chapter 13: Graphene-Based Polymer and Organic Solar Cells (3/5)
  91. Chapter 13: Graphene-Based Polymer and Organic Solar Cells (4/5)
  92. Chapter 13: Graphene-Based Polymer and Organic Solar Cells (5/5)
  93. Back Cover

Product information

  • Title: Organic Solar Cells
  • Author(s): Qiquan Qiao
  • Release date: December 2017
  • Publisher(s): CRC Press
  • ISBN: 9781351831215