Unique reference on the fundamentals, applications, and latest research in electroluminescence of organic molecules Organic Electroluminescence provides a comprehensive overview of organic electroluminescent materials from their history to the outlook of improved device performance. Divided into four parts, each section of the book covers important aspects of OLEDs such as device development, film properties, molecular electronics, and structure-activity relationships. The book also depicts correlations between device performance and molecular and device structure. An entire chapter is devoted…mehr
Unique reference on the fundamentals, applications, and latest research in electroluminescence of organic molecules Organic Electroluminescence provides a comprehensive overview of organic electroluminescent materials from their history to the outlook of improved device performance. Divided into four parts, each section of the book covers important aspects of OLEDs such as device development, film properties, molecular electronics, and structure-activity relationships. The book also depicts correlations between device performance and molecular and device structure. An entire chapter is devoted to improving device performance in real world applications using AI. Featuring contributions from experts from around the world, Organic Electroluminescence discusses sample topics including: * Fundamental concepts such as parameters, testing methods, and applications * Device fabrication techniques including electrode processing, organic layer deposition, encapsulation, light out-coupling enhancement, and spectral narrowing * Physical and chemical processes in OLEDs including charge injection and transport, exciton generation and decay, and reversible dipole reorientation * Physical and chemical properties of organic semiconductors in solutions and thin-films including photoluminescence quantum yield and excited-state lifetime * Single-molecule simulations including vertical transition, nonradiative decay, spin-orbital and spin-phonon coupling, and bond dissociation energy Organic Electroluminescence delivers advanced information for professionals seeking a thorough reference on the subject and for students learning about OLEDs.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Qisheng Zhang is a Professor in the Department of Polymer Science and Engineering at Zhejiang University in Hangzhou, China. He received his PhD at Changchun Institute of Applied Chemistry in 2005. He has worked at Fujian Institute of Research and Kyushu University and he has been selected to the Thousand Talent Program for Young Researchers in 2015. His research interests are in organic electroluminescent materials and molecular photochemistry.
Inhaltsangabe
Part I. Devices and Processing
Chapter: 1 Fundamentals of OLED 1.1 Brief History 1.2 Device Structure 1.2.1 Substrates and Electrodes 1.2.2 Organic Functional Layers 1.2.3 Passive and Active Matrix Addressing 1.2.4 Bottom- and Top-Emitting Devices 1.2.5 Inverted Devices 1.2.6 Tandem Devices 1.3 Parameters of OLEDs and their Testing Methods 1.3.1 Emission Spectrum and CIE Coordinate 1.3.2 Current Density-Voltage-Luminance Characteristics 1.3.3 Current Efficiency, Power Efficiency, and External Quantum Efficiency 1.3.4 Light Out-Coupling Efficiency 1.3.5 Device Lifetime 1.4 Application 1.4.1 Flexible Display 1.4.2 Transparent Displays 1.4.3 Microdisplay 1.4.4 Lighting
Part II. Physical and Chemical Aspects of Molecular Semiconductors
Chapter: 3 Physical and Chemical Processes in OLEDs 3.1 Charge Injection and Transport 3.2 Exciton Generation and Decay 3.3 Energy Transfer 3.4 Exciton-Exciton and Exciton-Polaron Annihilation 3.5 Reversible Dipole Reorientation 3.6 Electrochemical Reactions 3.7 Photochemical Reactions
Chapter 4: Physical and Chemical Properties of Organic Semiconductors in Solutions and Thin-Films 4.1 Emission Spectrum 4.2 Photoluminescence Quantum Yield 4.3 Excited-State Lifetime 4.4 Singlet and Triplet Energy Levels 4.5 Oxidation and Reduction Potentials 4.6 Charge Carriers Mobility 4.7 Polarized Light Emission 4.8 Thermal-Stability (thermal decomposition temperature and glass-transition temperature) 4.9 UV Light-Stability 4.10 Electrochemistry-Stability
Chapter 5: Correlation of Thin-Film Properties with Device Performance 5.1 Deviation of Electroluminescence Spectrum from Photoluminescence Spectrum 5.2 Factors Impacting on Current Density-Voltage Characteristics 5.3 Factors Impacting on Device Efficiency (at different current density) 5.4 Factors Impacting on Device Lifetime 5.5 Polarized Electroluminescence
Part III. Molecular Electronics and Photonics
Chapter 6: Basic Physical Parameters of Single Molecule 6.1 Zero-Zero Energies of Low-Lying Excited States 6.2 Radiative Decay Rate 6.3 Internal Conversion Rate 6.4 Intersystem Crossing Rate 6.5 Ionization Potential (IP) and Electron Affinity (EA) 6.6 Dipole Moment
Chapter 7: Molecular Interactions in Organic Semiconductor Thin-films 7.1 Bimolecular Processes 7.2 Parameters Impacting on Carrier Transport 7.3 Parameters Impacting on Energy Transfer Rate 7.4 A Classification of Upconversion Pathways 7.5 Parameters Impacting on Phosphorescence Yield 7.6 Parameters Impacting on TADF Yield 7.7 Dynamics of Intermolecular Interaction and its Influence on Physical Parameters
Chapter 8: Quantum-Chemical Insight into Structure-Property Relationships 8.1 Geometric and Electronic Configurations 8.2 Atomic Orbitals, Molecular Orbitals, and Electronic States 8.3 Rotational Levels and Vibrational Levels 8.4 Transition between States 8.5 Allowed and Forbidden Transitions (oscillator strength and transition dipole moment) 8.6 Coulomb Integral and Exchange Integral 8.7 Orbital Overlap Integral 8.8 Electronic Coupling and Transfer Integral 8.9 Franck-Condon Principle 8.10 Excited-State Relaxation 8.11 Energy Gap Law for Internal Conversion 8.12 Spin-Orbital Coupling and Heavy Atomic Effect 8.13 Pathways for Nonradiative Decay 8.14 Exciplex and Excimer 8.15 Bipolar Molecules
Part IV. Simulation Methods
Chapter 9: Single Molecule Simulation 9.1 Geometric and Electronic Structures of Ground-, Oxidation-, Reduction-, and Excited-States 9.2 Vertical Transition 9.3 Nonradiative Decay 9.4 Energy Difference between S1 and T1 9.5 Spin-Orbital Coupling 9.6 Spin-Phonon Coupling 9.7 Oxidation and Reduction Potentials 9.8 Reorganization Energy 9.9 Luminescence Quantum Yield 9.10 Bond Dissociation Energy
Chapter 10: Condensed-Matter Simulation 10.1 Bimolecular Arrangement 10.2 Energy Levels of Dimer 10.3 Molecular Orientation 10.4 Chain Structure of Polymer 10.5 Solid-State Solvation 10.6 Charge Carriers Mobility 10.7 Chemical Reaction Path
Chapter 11: Prediction of Device Performance from Materials and Device Structure 11.1 Outlook: From Molecular Structure to Device Performance 11.2 Missing Links in Theory 11.3 Finding New Strategies for Improving Device Performances by AI
Part II. Physical and Chemical Aspects of Molecular Semiconductors
Chapter: 3 Physical and Chemical Processes in OLEDs 3.1 Charge Injection and Transport 3.2 Exciton Generation and Decay 3.3 Energy Transfer 3.4 Exciton-Exciton and Exciton-Polaron Annihilation 3.5 Reversible Dipole Reorientation 3.6 Electrochemical Reactions 3.7 Photochemical Reactions
Chapter 4: Physical and Chemical Properties of Organic Semiconductors in Solutions and Thin-Films 4.1 Emission Spectrum 4.2 Photoluminescence Quantum Yield 4.3 Excited-State Lifetime 4.4 Singlet and Triplet Energy Levels 4.5 Oxidation and Reduction Potentials 4.6 Charge Carriers Mobility 4.7 Polarized Light Emission 4.8 Thermal-Stability (thermal decomposition temperature and glass-transition temperature) 4.9 UV Light-Stability 4.10 Electrochemistry-Stability
Chapter 5: Correlation of Thin-Film Properties with Device Performance 5.1 Deviation of Electroluminescence Spectrum from Photoluminescence Spectrum 5.2 Factors Impacting on Current Density-Voltage Characteristics 5.3 Factors Impacting on Device Efficiency (at different current density) 5.4 Factors Impacting on Device Lifetime 5.5 Polarized Electroluminescence
Part III. Molecular Electronics and Photonics
Chapter 6: Basic Physical Parameters of Single Molecule 6.1 Zero-Zero Energies of Low-Lying Excited States 6.2 Radiative Decay Rate 6.3 Internal Conversion Rate 6.4 Intersystem Crossing Rate 6.5 Ionization Potential (IP) and Electron Affinity (EA) 6.6 Dipole Moment
Chapter 7: Molecular Interactions in Organic Semiconductor Thin-films 7.1 Bimolecular Processes 7.2 Parameters Impacting on Carrier Transport 7.3 Parameters Impacting on Energy Transfer Rate 7.4 A Classification of Upconversion Pathways 7.5 Parameters Impacting on Phosphorescence Yield 7.6 Parameters Impacting on TADF Yield 7.7 Dynamics of Intermolecular Interaction and its Influence on Physical Parameters
Chapter 8: Quantum-Chemical Insight into Structure-Property Relationships 8.1 Geometric and Electronic Configurations 8.2 Atomic Orbitals, Molecular Orbitals, and Electronic States 8.3 Rotational Levels and Vibrational Levels 8.4 Transition between States 8.5 Allowed and Forbidden Transitions (oscillator strength and transition dipole moment) 8.6 Coulomb Integral and Exchange Integral 8.7 Orbital Overlap Integral 8.8 Electronic Coupling and Transfer Integral 8.9 Franck-Condon Principle 8.10 Excited-State Relaxation 8.11 Energy Gap Law for Internal Conversion 8.12 Spin-Orbital Coupling and Heavy Atomic Effect 8.13 Pathways for Nonradiative Decay 8.14 Exciplex and Excimer 8.15 Bipolar Molecules
Part IV. Simulation Methods
Chapter 9: Single Molecule Simulation 9.1 Geometric and Electronic Structures of Ground-, Oxidation-, Reduction-, and Excited-States 9.2 Vertical Transition 9.3 Nonradiative Decay 9.4 Energy Difference between S1 and T1 9.5 Spin-Orbital Coupling 9.6 Spin-Phonon Coupling 9.7 Oxidation and Reduction Potentials 9.8 Reorganization Energy 9.9 Luminescence Quantum Yield 9.10 Bond Dissociation Energy
Chapter 10: Condensed-Matter Simulation 10.1 Bimolecular Arrangement 10.2 Energy Levels of Dimer 10.3 Molecular Orientation 10.4 Chain Structure of Polymer 10.5 Solid-State Solvation 10.6 Charge Carriers Mobility 10.7 Chemical Reaction Path
Chapter 11: Prediction of Device Performance from Materials and Device Structure 11.1 Outlook: From Molecular Structure to Device Performance 11.2 Missing Links in Theory 11.3 Finding New Strategies for Improving Device Performances by AI
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