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 structure-property relationships to the outlook of improved device performance. Divided into three parts, the first section of the book covers fundamental aspects of OLEDs such as history, structures, properties, and operating and aging mechanisms. The second section provides quantum chemical and experimental insights into correlations between device performance, material characteristics, molecular physical parameters, and molecular structure. The last section is devoted to improving device performance in real world applications using molecular and device simulations.

Featuring contributions from experts from around the world, Organic Electroluminescence discusses sample topics including:

• Fundamental concepts in the fields of display, organic electronics, molecular photochemistry, and quantum chemistry
• Device fabrication, characterization and simulation techniques
• Physical and chemical processes in OLEDs including charge injection and transport, exciton generation and decay, reversible dipole reorientation, and chemical reactions
• Physical and chemical properties of organic semiconductors in solutions and thin-films including photoluminescence quantum yield, excited-state lifetime, and redox potential
• Single-molecule and condensed-matter simulations including vertical transition, nonradiative decay, spin-orbital and spin-phonon coupling, bond dissociation and charge transfer

Organic Electroluminescence delivers advanced information for professionals seeking a thorough reference on the subject and for students learning about OLEDs.

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.