For years, concepts and models relevant to the fields of molecular electronics and organic electronics have been invented in parallel, slowing down progress in the field. This book illustrates how synthetic chemists, materials scientists, physicists, and device engineers can work together to reach their desired, shared goals, and provides the knowledge and intellectual basis for this venture.
Supramolecular Materials for Opto-Electronics covers the basic principles of building supramolecular organic systems that fulfil the requirements of the targeted opto-electronic function; specific material properties based on the fundamental synthesis and assembly processes; and provides an overview of the current uses of supramolecular materials in opto-electronic devices. To conclude, a “what’s next” section provides an outlook on the future of the field, outlining the ways overarching work between research disciplines can be utilised.
Postgraduate researchers and academics will appreciate the fundamental insight into concepts and practices of supramolecular systems for opto-electronic device integration.
Table des matières
Self-Assembled Supramolecular Systems in Organic Electronics; Multicomponent Assembly Strategies for Supramolecular Systems; Low-Dimensional Supramolecular Assemblies on Surfaces; Rational Design of Supramolecular Photovoltaic Materials to Improve the Stability of Bulk Heterojunction Solar Cells; Amphiphilic Design for Supramolecular Materials with Opto-Electronic Functions; Chiral Supramolecular Structures as Spin Filters; Modeling Charge Transport in Organic Electronic Materials; Modeling of the Morphology and Charge Transport in Supramolecular Systems; Towards Highly Efficient Multilayer Pleds Based on all Solution Processing; Self-Assembled Mono and Multilayers for Functional Opto-Electronic Devices;