Charge Carrier Generation and Dynamics in Organic Semiconductor Systems / Fabian Bauch. Paderborn, 2026
Inhalt
- Introduction
- Fundamentals of Organic Semiconductors
- Chemical Background
- Opto-electronic Properties of Organic Semiconductors
- Electronic Structure Properties
- From the Schrödinger Equation to Potential Energy Surfaces: Adiabatic and Diabatic Descriptions
- Vibrational Modes
- Photoexcited States - The Exciton
- Environmental Influences
- Different Types of Electronic Interaction
- Interaction and Disorder in Organic Semiconductors
- Interaction of Organic Semiconductors with Solvent Molecules
- Static Approaches of Charge Transfer and State Transitions
- Dynamical Approaches for Electron-Nuclear Coupling
- Organic Semiconductors in Applications
- Single Charge Carriers in Organic Semiconductor Devices
- Photoexcited Charge Carriers in Organic Photovoltaic Devices
- Conclusion and Outlook
- Appendix
- Chemical Species
- Analytic Foundations
- Electronic Coupling: Generalized Mulliken Hush Method
- Spin-Orbit Coupling
- Oscillator Strength and Radiative Decay Rates from the Einstein Coefficient Relation
- Thermal Vibration Correlation Function
- Nuclear Ensemble Approach
- Reorganization Energy
- Reorganization Energy via the Four-Point Method
- Reorganization Energy Evaluation from Vibrational Mode Analysis
- Electronic-Structure Methods
- Bibliography