Molecular Electronics

Molecular Electronics

by Ioan Baldea
Released January 2016
Publisher(s): Jenny Stanford Publishing
ISBN: 9789814613910

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Book description

This book, a multi-authored volume comprising reviews written by leading scientists, discusses recent advances in the molecular electronics field. It emphasizes the need for studies beyond the low-bias regime, a fact on which the scientific community became aware in the last years. To make the book useful for scientists of various disciplines interested in "learning by doing," each chapter is written in a science/tutorial hybrid style, with its own introduction presenting fundamental concepts and frameworks. The content reflects the strong transdisciplinary efforts needed for substantial progress.

Table of contents

  1. Cover
  2. Contents (1/2)
  3. Contents (2/2)
  4. Preface
  5. Chapter 1: Single-Molecule Devices (1/8)
  6. Chapter 1: Single-Molecule Devices (2/8)
  7. Chapter 1: Single-Molecule Devices (3/8)
  8. Chapter 1: Single-Molecule Devices (4/8)
  9. Chapter 1: Single-Molecule Devices (5/8)
  10. Chapter 1: Single-Molecule Devices (6/8)
  11. Chapter 1: Single-Molecule Devices (7/8)
  12. Chapter 1: Single-Molecule Devices (8/8)
  13. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (1/6)
  14. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (2/6)
  15. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (3/6)
  16. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (4/6)
  17. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (5/6)
  18. Chapter 2: Making Contact to Molecular Layers: Linking Large Ensembles of Molecules to the Outside World (6/6)
  19. Chapter 3: Charge Transport in Dynamic Molecular Junctions (1/8)
  20. Chapter 3: Charge Transport in Dynamic Molecular Junctions (2/8)
  21. Chapter 3: Charge Transport in Dynamic Molecular Junctions (3/8)
  22. Chapter 3: Charge Transport in Dynamic Molecular Junctions (4/8)
  23. Chapter 3: Charge Transport in Dynamic Molecular Junctions (5/8)
  24. Chapter 3: Charge Transport in Dynamic Molecular Junctions (6/8)
  25. Chapter 3: Charge Transport in Dynamic Molecular Junctions (7/8)
  26. Chapter 3: Charge Transport in Dynamic Molecular Junctions (8/8)
  27. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (1/11)
  28. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (2/11)
  29. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (3/11)
  30. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (4/11)
  31. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (5/11)
  32. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (6/11)
  33. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (7/11)
  34. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (8/11)
  35. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (9/11)
  36. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (10/11)
  37. Chapter 4: Modulate and Control of Detailed Electron Transport of Single Molecule (11/11)
  38. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (1/14)
  39. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (2/14)
  40. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (3/14)
  41. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (4/14)
  42. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (5/14)
  43. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (6/14)
  44. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (7/14)
  45. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (8/14)
  46. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (9/14)
  47. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (10/14)
  48. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (11/14)
  49. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (12/14)
  50. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (13/14)
  51. Chapter 5: Vibronic Effects in Electron Transport through Single-Molecule Junctions (14/14)
  52. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (1/6)
  53. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (2/6)
  54. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (3/6)
  55. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (4/6)
  56. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (5/6)
  57. Chapter 6: Vibration Spectroscopy of Single Molecular Junctions (6/6)
  58. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (1/7)
  59. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (2/7)
  60. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (3/7)
  61. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (4/7)
  62. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (5/7)
  63. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (6/7)
  64. Chapter 7: Currents from Pulse-Driven Leads in Molecular Junctions: A Time-Independent Scattering Formulation (7/7)
  65. Chapter 8: Biomolecular Electronics (1/9)
  66. Chapter 8: Biomolecular Electronics (2/9)
  67. Chapter 8: Biomolecular Electronics (3/9)
  68. Chapter 8: Biomolecular Electronics (4/9)
  69. Chapter 8: Biomolecular Electronics (5/9)
  70. Chapter 8: Biomolecular Electronics (6/9)
  71. Chapter 8: Biomolecular Electronics (7/9)
  72. Chapter 8: Biomolecular Electronics (8/9)
  73. Chapter 8: Biomolecular Electronics (9/9)
  74. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (1/6)
  75. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (2/6)
  76. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (3/6)
  77. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (4/6)
  78. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (5/6)
  79. Chapter 9: EC-STM/STS of Redox Metalloproteins and Co-Factors (6/6)
  80. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (1/9)
  81. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (2/9)
  82. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (3/9)
  83. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (4/9)
  84. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (5/9)
  85. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (6/9)
  86. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (7/9)
  87. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (8/9)
  88. Chapter 10: Electron Transport in Atomistic Nanojunctions from Density Functional Theory in Scattering Approaches (9/9)
  89. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (1/9)
  90. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (2/9)
  91. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (3/9)
  92. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (4/9)
  93. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (5/9)
  94. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (6/9)
  95. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (7/9)
  96. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (8/9)
  97. Chapter 11: Transition Voltage Spectroscopy: An Appealing Tool of Investigation in Molecular Electronics (9/9)
  98. Back Cover

Product information

  • Title: Molecular Electronics
  • Author(s): Ioan Baldea
  • Release date: January 2016
  • Publisher(s): Jenny Stanford Publishing
  • ISBN: 9789814613910