Advanced materials researchers demonstrate how energy levels align in organic-based technologies
Photo: MSE doctoral candidate, Mark T. Greiner
November 7, 2011
University of Toronto materials science and engineering (MSE) researchers have demonstrated for the first time the key mechanism behind how energy levels align in a critical group of advanced materials. This discovery is a significant breakthrough in the development of sustainable technologies such as dye-sensitized solar cells and organic light-emitting diodes (OLEDs).
Transition metal oxides, which are best-known for their application as super-conductors, have made possible many sustainable technologies developed over the last two decades, including organic photovoltaics and organic light-emitting diodes. While it is known that these materials make excellent electrical contacts in organic-based devices, it wasn’t known why.
Until now.
In research published today in Nature Materials, MSE doctoral researcher Mark T. Greiner and Professor Zheng-Hong Lu, Canada Research Chair in Organic Optoelectronics, lay out the blueprint that conclusively establishes the principle of energy alignment at the interface between transition metal oxides and organic molecules.
“The energy-level of molecules on materials surfaces is like a massive jigsaw puzzle that has challenged the scientific community for a very long time,” says Professor Lu. “There have been a number of suggested theories with many critical links missing. We have been fortunate to successfully build these links to finally solve this decades-old puzzle.”
With this piece of the puzzle solved, this discovery could enable scientists and engineers to design simpler and more efficient organic solar cells and OLEDs to further enhance sustainable technologies and help secure our energy future.
The paper, entitled “Universal Energy-Level Alignment of Molecules on Metal Oxides,” is available online.
This publication marks the third major research paper in 2011 for Professor Lu’s Organic Optoelectronics Research Group. Science published PhD Candidate Michael G. Helander’s “Chlorinated Indium Tin Oxide Electrodes with High Work Function for Organic Device Compatibility” on April 14 and Nature Phototonics published PhD Candidate Zhibin Wang’s “Unlocking the Full Potential of Organic Light-Emitting Diodes on Flexible Plastic” on October 30.