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Researchers achieve major breakthrough in flexible electronics

Date:
January 13, 2017
Source:
National University of Singapore
Summary:
Semiconductors, which are the very basic components of electronic devices, have improved our lives in many ways. They can be found in lighting, displays, solar modules and microprocessors that are installed in almost all modern day devices, from mobile phones, washing machines, and cars, to the emerging Internet of Things. To innovate devices with better functionality and energy efficiency, researchers are constantly looking for better ways to make them, in particular from earth-abundant materials using eco-friendly processes.
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Semiconductors, which are the very basic components of electronic devices, have improved our lives in many ways. They can be found in lighting, displays, solar modules and microprocessors that are installed in almost all modern day devices, from mobile phones, washing machines, and cars, to the emerging Internet of Things. To innovate devices with better functionality and energy efficiency, researchers are constantly looking for better ways to make them, in particular from earth-abundant materials using eco-friendly processes. Plastic or organic electronics, which is made from organic carbon-based semiconductors, is one such group of technologies that can potentially provide flexible, light-weight, large-area and additively-manufactured devices, which are attractive for some types of applications.

To make high-performance devices however, good ohmic contacts with low electrical resistances are required to allow the maximum current to flow both ways between the electrode and the semiconductor layers. Recently, a team of scientists from the National University of Singapore (NUS) has successfully developed conducting polymer films that can provide unprecedented ohmic contacts to give superior performance in plastic electronics, including organic light-emitting diodes, solar cells and transistors. The research findings have been recently published in the journal Nature.

The key these researchers discovered is to be able to design polymer films with the desired extreme work functions needed to generally make ohmic contacts. Work function is the minimum amount of energy needed to liberate an electron from the film surface into vacuum. The researchers showed that work functions as high as 5.8 electron-volts and as low as 3.0 electron-volts can now be attained for films that can be processed from solutions at low cost.

"To design such materials, we developed the concept of doped conducting polymers with bonded ionic groups, in which the doped mobile charges -- electrons and holes -- cannot dissipate away because their counter-balancing ions are chemically bonded," explained Dr Png Rui-Qi, a senior research fellow from the Department of Physics at the NUS Faculty of Science, who led the device research team. "As a result, these conducting polymers can remain stable despite their extreme work functions and provide the desired ohmic contacts."

This breakthrough is the result of a collaboration with the materials chemistry team led by Associate Professor Chua Lay-Lay from the Department of Chemistry at the NUS Faculty of Science, the physics team led by Associate Professor Peter Ho from the Department of Physics from the same faculty, and scientists from Cambridge Display Technology Ltd, a subsidiary of Sumitomo Chemical Co., Ltd.

"The lack of a general approach to make ohmic contacts has been a key bottleneck in flexible electronics. Our work overcomes this challenge to open a path to better performance in a wide range of organic semiconductor devices," explained Dr Png Rui-Qi. "We are particularly thrilled about this Singapore-led innovation," she added.

Commenting on the significance of the work, Assoc Prof Chua said, "The close partnership of the chemists and physicists has made this innovation possible. We are now working with our industrial partner to further develop this technology."


Story Source:

Materials provided by National University of Singapore. Note: Content may be edited for style and length.


Journal Reference:

  1. Cindy G. Tang, Mervin C. Y. Ang, Kim-Kian Choo, Venu Keerthi, Jun-Kai Tan, Mazlan Nur Syafiqah, Thomas Kugler, Jeremy H. Burroughes, Rui-Qi Png, Lay-Lay Chua, Peter K. H. Ho. Doped polymer semiconductors with ultrahigh and ultralow work functions for ohmic contacts. Nature, 2016; 539 (7630): 536 DOI: 10.1038/nature20133

Cite This Page:

National University of Singapore. "Researchers achieve major breakthrough in flexible electronics." ScienceDaily. ScienceDaily, 13 January 2017. <www.sciencedaily.com/releases/2017/01/170113090448.htm>.
National University of Singapore. (2017, January 13). Researchers achieve major breakthrough in flexible electronics. ScienceDaily. Retrieved December 3, 2024 from www.sciencedaily.com/releases/2017/01/170113090448.htm
National University of Singapore. "Researchers achieve major breakthrough in flexible electronics." ScienceDaily. www.sciencedaily.com/releases/2017/01/170113090448.htm (accessed December 3, 2024).

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