Printing organic transistors


High-speed low-power printed transistors could lead to new display technologies


Credit: © 2020 Kitahara et al.

The chances are you are reading these words on a smartphone or computer screen. For around the last 10 years, these types of screens have been based on a display technology composed of so-called thin film transistors. These are inorganic transistors which require very little power, and they have proven themselves very capable given their widespread adoption. But they have some limits which researchers have been busy trying to overcome.

“We explore new ways to improve upon thin film transistors, such as new designs or new methods of manufacture,” said Gyo Kitahara, a Ph.D. student from the Department of Applied Physics. “Organic thin film transistors, for example, have a bright future in LCD screen devices. Compared to the inorganic kind currently used, we expect the organic kind to be useful in low-cost, large-area, lightweight and wearable electronic products, especially by using printing-based production technologies.”

The idea of organic thin film transistors itself is not new, but the ability to print such devices, which would allow for a design revolution, has eluded industry and academics, until now. Professor Tatsuo Hasegawa of the Department of Applied Physics, Kitahara and their team came up with a way to print organic semiconductor films, the basis of these transistors, on a special surface that is highly solution-repellent, or lyophobic. This means ordinarily the surface would repel the materials required to print the structure of the transistor, which seems counterintuitive as to why such a surface would be useful at all. But lyophobic surfaces are responsible for creating transistor structures that are finely tuned for high performance. So how did the researchers overcome their repellent nature?

“We made use of a fluidic property you probably see every time you wash your hands with soap,” said Kitahara. “Soap bubbles can hold a shape by lowering the surface tension of liquid. We presume that the soap-film mechanism should be effective for formation of a thin liquid layer on lyophobic surfaces in spite of the repellent forces. Solid semiconductor films can be formed and grown via the formation of thin liquid layers during the printing processes.”

With this hurdle of how to print organic transistors overcome, other researchers can build on the team’s findings and find ways to scale this method up. With a proliferation of large, flexible or wearable devices, Hasegawa’s team dreams of seeing a convergence between the real world and virtual world in ways we’ve never seen before.

“After having experimented by trial and error, we eventually found that the use of a special U-shaped metal-film pattern seems to be effective for uniform film growth thanks to the way it creates a thin liquid layer on lyophobic surfaces,” said Kitahara. “We anticipated the results beforehand to some extent, but the success of these findings was finally demonstrated and obtained after overcoming several difficulties, which brought great pleasure and happiness to me.”


Journal article

Gyo Kitahara, Satoru Inoue, Toshiki Higashino, Mitsuhiro Ikawa, Taichi Hayashi, Satoshi Matsuoka, Shunto Arai, Tatsuo Hasegawa. “Meniscus-controlled printing of single-crystal interfaces showing extremely sharp-switching transistor operation”, Science Advances in press.

DOI: 10.1126/sciadv.abc8847

Useful links

Hasegawa-Arai Lab –

Department of Applied Physics –

Graduate School of Engineering –

This work was supported by JST CREST Grant No. JPMJCR18J2, JST A-STEP Grant No. JPMJTR1923, JSPS KAKENHI Grants No. JP18H03875, and Leadership Development Program for Ph.D. (LDPP) in the University of Tokyo.

Research Contact

Gyo Kitahara

Department of Applied Physics, Graduate School of Engineering,

The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, JAPAN

Email: [email protected]

Press Contact

Mr. Rohan Mehra

Division for Strategic Public Relations, The University of Tokyo

7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8654, JAPAN

Email: [email protected]

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Media Contact
Gyo Kitahara
[email protected]

Original Source

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