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Intersecting light beams key in transformative 3D printer potential

Date:
June 6, 2022
Source:
Queensland University of Technology
Summary:
Researchers have used intersecting light beams to control chemical reactions in an advanced material, paving the way for future use in 3D printers that print entire layers, instead of single points, at a time.
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QUT researchers have used intersecting light beams to control chemical reactions in an advanced material, paving the way for future use in 3D printers that print entire layers, instead of single points, at a time.

QUT's Centre for Materials Science interdisciplinary research team, made up of Dr Sarah Walden, Leona Rodrigues, Dr Jessica Alves, Associate Professor James Blinco, Dr Vinh Truong, and ARC Laureate Fellow Professor Christopher Barner-Kowollik, have published their research in Nature Communications.

Dr Walden said light was a particularly desirable tool for activating chemical processes, because of the precision it offered in starting a reaction.

"Most of the work QUT's Soft Matter Materials Group researchers have done in the past with light has been to use a laser beam to start and stop a chemical reaction along the entire volume where the light strikes the material," Dr Walden said.

"In this case, we have two different coloured light beams, and the reaction only occurs where the two beams intersect.

"We use one colour of light to activate one molecule, and the second colour of light to activate another molecule. And where the two light beams meet, the two activated molecules react to form a solid material.

"Normally, in a 3D printer, the inkjet moves around in two dimensions, slowly printing one 2D layer before moving up to print another layer on top.

"But using this technology, you could have a whole two-dimensional sheet activated, and print the entire sheet at once."

Professor Barner-Kowollik said such two colour activated materials are currently very rare.

"This project is about proving the viability of the ink for future generation of printers," he said.

Professor Barner-Kowollik, whose career is focused on the power and possibilities of light in materials science, was recently recognised with Australia's highest prize for chemistry, the 2022 David Craig medal, awarded by the Australian Academy of Science.

Professor Barner-Kowollik said one of the challenges of the project was to find two molecules that could be activated by two different colours of light and then have them react together.

"This is where the innovation comes from," Professor Barner-Kowollik said.

"You want a molecule to be activated with one colour of light but not the other colour, and vice versa.

"That's not easy to find, it's actually quite hard to find."

Dr Truong, after much work, was able to find two molecules that reacted to the lights in the required manner and combined to form a very solid material.

"In our chemical design, both light activated processes are reversible," Dr Truong said.

"Hence we can control exactly when and where the solid material may form."

The researchers are from QUT's School of Chemistry and Physics.


Story Source:

Materials provided by Queensland University of Technology. Note: Content may be edited for style and length.


Journal Reference:

  1. Sarah L. Walden, Leona L. Rodrigues, Jessica Alves, James P. Blinco, Vinh X. Truong, Christopher Barner-Kowollik. Two-colour light activated covalent bond formation. Nature Communications, 2022; 13 (1) DOI: 10.1038/s41467-022-30002-6

Cite This Page:

Queensland University of Technology. "Intersecting light beams key in transformative 3D printer potential." ScienceDaily. ScienceDaily, 6 June 2022. <www.sciencedaily.com/releases/2022/06/220606105625.htm>.
Queensland University of Technology. (2022, June 6). Intersecting light beams key in transformative 3D printer potential. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2022/06/220606105625.htm
Queensland University of Technology. "Intersecting light beams key in transformative 3D printer potential." ScienceDaily. www.sciencedaily.com/releases/2022/06/220606105625.htm (accessed November 20, 2024).

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