EXTMOS

eXtended Model of Organic Semiconductors

Abstract

XMOS’ main objective is to create a materials model and the related user friendly code that will focus on charge transport in doped organic semiconductors. Its aims are (i) to reduce the time to market of (a) multilayer organic light emitting devices, OLEDs, with predictable efficiencies and long lifetimes (b) organic thin film transistors and circuits with fast operation. (ii) to reduce production costs of organic devices by enabling a fully solution processed technology. Development costs and times will be lowered by identifying dopants that provide good device performance, reducing the number of dopant molecules that need to be synthesized and the materials required for trial devices. (iii) to reduce design costs at circuit level through an integrated model linking molecular design to circuit operation. Screening imposes the following requirements from the model 1. An improved understanding of dopant/host interactions at the molecular level. Doping efficiencies need to be increased to give better conducting materials. For OLEDs, dopants should not absorb visible light that lowers output nor ultraviolet light that can cause degradation. 2. An ability to interpret experimental measurements used to identify the best dopants. 3. The possibility of designing dopants that are cheap and (photo)chemically robust and whose synthesis results in fewer unwanted impurities, and that are less prone to clustering. The XMOS model is at the discrete mesoscopic level with embedded microscopic electronic structure and molecular packing calculations. Modules at the continuum and circuit levels are an integral part of the model. It will be validated by measurements on single and multiple layer devices and circuits and exploited by 2 industrial end users and 2 software vendors. US input is provided by an advisory council of 3 groups whose expertise complements that of the partners.

Project details

Unibo Team Leader: Claudio Zannoni

Unibo involved Department/s:
Dipartimento di Chimica Industriale "Toso Montanari"

Coordinator:
The University Of Bath-Ukoln(United Kingdom)

Other Participants:
Cambridge Display Technology Ltd (United Kingdom)
Cea-Commissariat A L'Energie Atomique Et Aux Energies Alternatives (France)
Novaled Gmbh (Germany)
Institut de Recherche et d'Histoire des Textes (France)
FlexEnable Ltd. (United Kingdom)
Imec (Belgium)
Université De Mons (Umons) (Belgium)
Silvaco Europe Ltd (United Kingdom)
Nanosim GmbH (Germany)
Kit Karlsruhe Institute Of Technology (Germany)
ALMA MATER STUDIORUM - Università di Bologna (Italy)
Max Planck - Innovation Gmbh (Germany)

Total Eu Contribution: Euro (EUR) 4.998.000,00
Project Duration in months: 48
Start Date: 01/07/2015
End Date: 30/06/2019

Cordis webpage

Industry, innovation and infrastructure This project contributes to the achievement of the Sustainable Development Goals of the UN 2030 Agenda.

This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 646176 This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 646176