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Printable circuits that can work on fabric, plastic and even fruit

Date:
October 26, 2022
Source:
American Chemical Society
Summary:
Remember iron-on decals? All you had to do was print something out on special paper with a home printer, then transfer it onto a T-shirt using an iron. Now, scientists have developed a very similar scheme, but instead of family photos or logos, it prints circuitry. The method can print functional circuits onto items ranging from ukuleles to teacups.
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Remember iron-on decals? All you had to do was print something out on special paper with a home printer, then transfer it onto a T-shirt using an iron. Now, scientists have developed a very similar scheme, but instead of family photos or logos, it prints circuitry. The method, reported in ACS Applied Materials & Interfaces, can print functional circuits onto items ranging from ukuleles to teacups.

As electronics continue to evolve, so too do the circuit boards that control them. Most boards used today are rigid, built on solid fiberglass backings. As electronic systems are integrated into floppy and pliable items, such as clothing and soft robots, electronics need to be flexible too. This has led to increased interest in liquid metal circuits, which often include a special alloy of gallium metal that is a liquid at room temperature. One way to make these devices is to print them out with a modified inkjet or 3D printer. But these methods require complicated steps and sophisticated equipment, making the resulting devices expensive and unsuitable for large-scale manufacturing. To make the fabrication process quicker, easier and cheaper, Xian Huang and colleagues wanted to develop a method of creating liquid metal circuitry using a desktop laser printer that could place the electronics onto many types of surfaces.

To create the circuits, the researchers printed out a connected design onto heat-transferrable thermal paper with an ordinary laser printer. The printer laid down a carbon-based toner, which was transferred to a pane of glass by heating it. These toner patterns roughened the surface and created a hydrophobic gap of air between the carbon and the liquid metal. This prevented the metal from sticking when brushed on top, so the electronic ink-based pattern only adhered on the exposed parts of the surface.

This circuit could then be stuck directly to a smooth surface, such as a plastic soda bottle. If the surface was too uneven, like the bumpy skin of an orange, the device was first placed on a piece of flexible plastic, then onto the rougher surface. Regardless of how they were attached, however, the simple electronics all functioned as intended on their various substrates -- from displaying images, to RFID tagging, to sensing temperature and sound. The researchers say that this protocol should greatly expand the applications of liquid metal circuits.

The authors acknowledge funding from the Key Research and Development Program of Zhejiang Province and the National Natural Science Foundation of China.

Video: https://youtu.be/HQattovte08


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Materials provided by American Chemical Society. Note: Content may be edited for style and length.


Journal Reference:

  1. Rui Guo, Tianyu Li, Ziyue Wu, Chunxue Wan, Jing Niu, Wenxing Huo, Haixia Yu, Xian Huang. Thermal Transfer-Enabled Rapid Printing of Liquid Metal Circuits on Multiple Substrates. ACS Applied Materials & Interfaces, 2022; 14 (32): 37028 DOI: 10.1021/acsami.2c08743

Cite This Page:

American Chemical Society. "Printable circuits that can work on fabric, plastic and even fruit." ScienceDaily. ScienceDaily, 26 October 2022. <www.sciencedaily.com/releases/2022/10/221026103134.htm>.
American Chemical Society. (2022, October 26). Printable circuits that can work on fabric, plastic and even fruit. ScienceDaily. Retrieved December 20, 2024 from www.sciencedaily.com/releases/2022/10/221026103134.htm
American Chemical Society. "Printable circuits that can work on fabric, plastic and even fruit." ScienceDaily. www.sciencedaily.com/releases/2022/10/221026103134.htm (accessed December 20, 2024).

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