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High Performance Thin Films from Solution Processible Two-Dimensional Nanoplates

技術優勢

Higher conductivity than similar conductive colloidal inksInexpensive deposition method when compared to traditional methodsGreater mechanical compliance for flexible applications

技術應用

Printed electronicsFlexible electronicsConformal, conductive coatings

詳細技術說明

UCLA researchers in the departments of Chemistry and Materials Science have recently developed a novel material based on semiconducting nanoplates for use in flexible, printed electronics. Researchers started by carefully growing two-dimensional nanoplates and then suspending them in solution to make colloidal ink. The nanoplate ink can be directly printed onto plastic substrates, while the colloidal nature of the ink reduces clumping and allows for uniform deposition. The resulting thin film is highly conductive due to the high surface area connectivity that results from the stacked nanoplates. The nanostructure additionally allows for the greater mechanical compliance needed in flexible applications. The nanoplate ink allows for highly conductive thin films to be directly printed onto flexible plastic substrates.

*Abstract

UCLA researchers in the departments of Chemistry and Materials Science have recently developed a novel material for use in flexible, printed electronics.

*Applications

• Printed electronics
• Flexible electronics
• Conformal, conductive coatings

*Principal Investigation

Name: Xiangfeng Duan

Department:

Name: Yu Huang

Department:

其他

State Of Development

A working prototype has been developed and tested.

Background

Producing cheap, lightweight, and flexible electronics requires depositing electronic materials onto flexible, plastic substrates. Traditional methods of material deposition require high temperatures and/or pressures in order to produce high quality materials that are sufficiently conductive. The current material of choice for use in conductive thin films is indium tin oxide (ITO); however the cost and quality of the material make it prohibitive for cheap, flexible electronics. An ideal conductive thin film would maintain its excellent electronic transport characteristics while granting additional benefits, such as flexibility and the ability to be printed directly onto plastic substrates.

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Tech ID/UC Case

25180/2015-175-0

Related Cases

2015-175-0

國家/地區

美國