Case 2011-558
UCLA researchers in the Department of Materials Science and Engineering have developed a novel class of conjugated polymers for photo-electronic device applications.
BACKGROUND
Conjugated polymers are of interest for active layer materials in polymer-based light emission devices, solar cells, field effect transistors, photodetectors, batteries, supercapacitors, and sensors. They have the potential to lead to low-cost, flexible, lightweight, and easy processable materials for energy generation applications. However, current polymer materials either suffer from a lack of broad solar absorption or relatively low carrier mobility. Previous conjugated polymer-based solar cells have low efficiencies (~7%), leaving a need for new polymer materials that have both high mobility and low bandgaps in order to harvest a broad spectrum of sunlight.
INNOVATION
A research team led by Professor Yang Yang has invented a novel class of conjugated polymers with low bandgaps (1.4 eV-1.5 eV). These polymer materials have a tunable structure and electronic properties, thereby allowing the use of this material to fit into a variety of applications. Implementing these unique polymers into tandem solar cell devices has resulted in power conversion efficiencies as high as 9.5%, which show excellent stability and reproducibility. These devices have better charge transport properties than other similar materials, giving rise to higher open circuit voltage and short circuit current. With optimization, there is a possibility of achieving 15% efficiency.
APPLICATIONS
- Organic photovoltaic devices
- Tandem solar cells
- Light emitting diodes
- Field effect transistors
- Photodetectors
- Batteries and supercapacitors
- Sensors
ADVANTAGES
- Low bandgap polymers (1.4 eV to 1.5 eV)
- Easy structural modification of polymers
- Control of optical, electrochemical, and electronic properties
- Improved power conversion efficiency
- Excellent solar cell stability and reproducibility
STATE OF DEVELOPMENT
Prototype devices with power conversion efficiency as high as 9.5% have been fabricated and extensively tested, with the prospects of reaching 15% efficiency.
RELATED MATERIALS
L. Dou, J. Gao, E. Richard, J. You, C. C. Chen, K. C. Cha, Y. He, G. Li, and Ya. Yang. Systematic Investigation of Benzodithiophene- and Diketopyrrolopyrrole-Based Low-Bandgap Polymers Designed for Single Junction and Tandem Polymer Solar Cells. Journal of American Chemical Society. 2012.