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Future electronic components to be printed like newspapers

Date:
July 19, 2018
Source:
Purdue University
Summary:
A new manufacturing technique uses a process similar to newspaper printing to form smoother and more flexible metals for making ultrafast electronic devices.
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A new manufacturing technique uses a process similar to newspaper printing to form smoother and more flexible metals for making ultrafast electronic devices.

The low-cost process, developed by Purdue University researchers, combines tools already used in industry for manufacturing metals on a large scale, but uses the speed and precision of roll-to-roll newspaper printing to remove a couple of fabrication barriers in making electronics faster than they are today.

Cellphones, laptops, tablets, and many other electronics rely on their internal metallic circuits to process information at high speed. Current metal fabrication techniques tend to make these circuits by getting a thin rain of liquid metal drops to pass through a stencil mask in the shape of a circuit, kind of like spraying graffiti on walls.

"Unfortunately, this fabrication technique generates metallic circuits with rough surfaces, causing our electronic devices to heat up and drain their batteries faster," said Ramses Martinez, assistant professor of industrial engineering and biomedical engineering.

Future ultrafast devices also will require much smaller metal components, which calls for a higher resolution to make them at these nanoscale sizes.

"Forming metals with increasingly smaller shapes requires molds with higher and higher definition, until you reach the nanoscale size," Martinez said. "Adding the latest advances in nanotechnology requires us to pattern metals in sizes that are even smaller than the grains they are made of. It's like making a sand castle smaller than a grain of sand."

This so-called "formability limit" hampers the ability to manufacture materials with nanoscale resolution at high speed.

Purdue researchers have addressed both of these issues -- roughness and low resolution -- with a new large-scale fabrication method that enables the forming of smooth metallic circuits at the nanoscale using conventional carbon dioxide lasers, which are already common for industrial cutting and engraving.

"Printing tiny metal components like newspapers makes them much smoother. This allows an electric current to travel better with less risk of overheating," Martinez said.

The fabrication method, called roll-to-roll laser-induced superplasticity, uses a rolling stamp like the ones used to print newspapers at high speed. The technique can induce, for a brief period of time, "superelastic" behavior to different metals by applying high-energy laser shots, which enables the metal to flow into the nanoscale features of the rolling stamp -- circumventing the formability limit.

"In the future, the roll-to-roll fabrication of devices using our technique could enable the creation of touch screens covered with nanostructures capable of interacting with light and generating 3D images, as well as the cost-effective fabrication of more sensitive biosensors," Martinez said.


Story Source:

Materials provided by Purdue University. Note: Content may be edited for style and length.


Journal Reference:

  1. Debkalpa Goswami, Juan C. Munera, Aniket Pal, Behnam Sadri, Caio Lui P. G. Scarpetti, Ramses V. Martinez. Roll-to-Roll Nanoforming of Metals Using Laser-Induced Superplasticity. Nano Letters, 2018; 18 (6): 3616 DOI: 10.1021/acs.nanolett.8b00714

Cite This Page:

Purdue University. "Future electronic components to be printed like newspapers." ScienceDaily. ScienceDaily, 19 July 2018. <www.sciencedaily.com/releases/2018/07/180719104831.htm>.
Purdue University. (2018, July 19). Future electronic components to be printed like newspapers. ScienceDaily. Retrieved December 20, 2024 from www.sciencedaily.com/releases/2018/07/180719104831.htm
Purdue University. "Future electronic components to be printed like newspapers." ScienceDaily. www.sciencedaily.com/releases/2018/07/180719104831.htm (accessed December 20, 2024).

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