Nanothin printing of electronics hardware could slash costs

Engineering researchers have developed a 2D printing process using liquid metals that they say could create new ways of creating more advanced and energy efficient computing hardware that is manufactured at the nanoscale.

Dr Mohammad Ghasemian.

The process comes amid increasing worldwide demand for memory devices, which require significant amounts of energy to produce and use.

“Reducing the temperature at which zirconium and hafnium become liquid is crucial to developing lower-cost electrical devices as far less energy is required,” said Dr Mohammad Ghasemian, the study’s lead author from the School of Chemical and Biomolecular Engineering.

Developed by University of Sydney engineers and published in Small, the researchers first combined tin, zirconium and hafnium in a precise ratio. This enabled the alloy to be melted below 500 degrees, far lower than the individual melting points for zirconium (1855 degrees) and hafnium (2227 degrees).

Think of it like a marble coated in ink. The alloy is like a solvent that allows us to remove that ink and then use it for printing.

Dr Mohammad Ghasemian, School of Chemical and Biomolecular Engineering

The liquid metal alloy has a thin oxide layer or ‘crust’ while maintaining a liquid centre. It is used to harvest the ultra-thin tin oxide nanosheets doped with hafnium zirconium oxide.

“Tin is abundant, low cost and can be used at a large scale for the manufacture of critical semiconductors, transistors and memory chips,” said Dr Ghasemian.

“Though hafnium zirconium oxide is a well-known ferroelectric material used in nanoscale applications, like memory devices and sensors, obtaining nanosheets using conventional techniques is both difficult and costly,” he said.

How the process worked. Image: Mohammad Ghasemian and co-authors.

Applying the tin-zirconium-hafnium alloy allowed the team to harvest the nanothin tin oxide layer doped with hafnium zirconium oxide through exfoliation – lifting it from its liquid surface – so it could then be 2D printed on a substrate as ferroelectric nanosheets. These sheets are designed to form the basis of next generation computing hardware, from semiconductors to memory chips.

“Think of it like a marble coated in ink,” Dr Ghasemian said. “The alloy is like a solvent that allows us to remove that ink and then use it for printing. Our process allows us to harvest this precious crust layer and turn it into ultra-thin sheets, which are then used to manufacture electronics.”

“It could be a new source of functional 2D materials which are not accessible by conventional methods. This process allows us to introduce ferroelectricity into much smaller, 2D metal oxides, allowing for the development of next generation nanoelectronics at low temperatures.”

DECLARATION:

The researchers declare no external interests. The research was funded by Australian Research Council Laureate Fellowship grant (FL180100053), the ARC Centre of Excellence FLEET (CE170100039), and the ARC Industrial Hub (IH210100025). The authors also acknowledge the facilities, resources and assistance of Microscopy Australia, UNSW, National Computational Infrastructure and the Pawsey Supercomputing Research Centre.

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