Title :
Multiscale Modeling of Charge and Energy Transport in Organic Light-Emitting Diodes and Photovoltaics
Author :
Walker, Alison B.
Author_Institution :
Dept. of Phys., Univ. of Bath, Bath, UK
Abstract :
Modelling organic devices is an outstanding challenge because device performance is very sensitive to how the molecules are packed and the films are highly disordered. An understanding of charge and exciton (bound electron-hole pair) transport in these materials is important if organic light-emitting diodes are to be exploited in displays, lighting, photovoltaics, transistors, and sensors. This paper discusses methods we have pioneered for predicting charge and exciton transport, in which polymer chains are explicitly modeled and charge and exciton transfer rates are taken from electronic structure theory. Monte Carlo and drift diffusion device models that link device performance with morphology are also covered. The focus here is on polymers, but there is much in common with small molecule organic materials.
Keywords :
Monte Carlo methods; Organic electronics; carrier mobility; conducting polymers; excitons; molecular electronics; organic light emitting diodes; photovoltaic cells; semiconductor device models; Monte Carlo models; OLED; bound electron-hole pair; charge transport; drift diffusion device models; electronic structure theory; energy transport; exciton transport; multiscale modeling; organic light-emitting diodes; photovoltaics; polymer chains; Active matrix organic light emitting diodes; Chemical elements; Computer displays; Excitons; Flat panel displays; Light emitting diodes; Organic light emitting diodes; Organic materials; Photovoltaic cells; Thin film transistors; Charge carrier mobility; diodes; displays; energy conversion; excitons; modeling; photovoltaic cells; plastic films;
Journal_Title :
Proceedings of the IEEE
DOI :
10.1109/JPROC.2009.2023810
