image: Heyou Zhang and collaborator Calum Kinnear working in the NanoScience Laboratory at The University of Melbourne's School of Chemistry. view more
Credit: Gavan Mitchell & Michelle Gough (University of Melbourne/Exciton Science).
Special anti-counterfeiting and chemical sensing tools that we can use with our eyes could be created thanks to a new nanoscale building method.
In a world-first, researchers at the ARC Centre of Excellence in Exciton Science have been able to arrange tiny rods made from gold in exact patterns, and in numbers large enough for practical use. The results have been published in the journal Advanced Functional Materials.
Importantly, these gold rods can be arranged to generate a variety of colours, which change according to how they are viewed.
That makes them a great anti-counterfeiting feature. For example, if used on a banknote or passport, they could be helpful for cashiers or customs agents.
They can also be modified to turn different colours in the presence of chemicals, acting as a warning for dangerous levels of carbon monoxide and other gases.
Although these effects have been observed before, it was not possible to make them at a size visible to the naked eye. A new approach to chemical assembly was needed.
Consider this: Getting the bricks in a house to match is simple enough. Go a bit smaller, and kids can do the same with Lego. But how do you build things accurately at the nanoscale?
A nanometre is approximately one billionth the size of a metre. To put things in perspective, a sheet of paper is about 100,000 nanometres thick, and your fingernails grow about one nanometre every second. So, unless you're Ant Man and can shrink to the subatomic level, it's a tough task.
But fortunately, you don't need to be an Avenger to get the job done. Lead author Heyou Zhang, a PhD candidate at The University of Melbourne, has used a technique called electrophoretic deposition (EPD).
"The whole idea of my PhD is to be able to better control single nanoparticles. Builders construct houses, brick by brick, and they can put each brick where they want," Heyou said.
"I want to use nanoparticles in a similar way.
"But at the nanometre scale, you can't move nanoparticles yourself. They are invisible. You need to use a method to drive or push the particle into a certain position."
EPD involves applying an electric field of a certain strength to the materials, and using the separation of positive and negative charges to push the rods into place.
Heyou explained: "You have a positive potential and, if the particle is negative, they attract each other. If I have the positive potential on the side of a wall and I have some holes on the wall, the particle can only be attracted to those holes."
With the technique, Heyou and his colleagues are able to build collections of over one million nanorods per square millimetre, in patterns of their choosing.
As well as anticounterfeiting and chemical sensing, the assembly method could have applications in renewable energy, smart phones, laptops and efficient lighting.
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Media contacts:
Guangzhou UTC +8
First author: Heyou Zhang (heyouz@student.unimelb.edu.au)
AEST, UTC +10.
Senior author: Professor Paul Mulvaney (mulvaney@unimelb.edu.au)
Iain Strachan, Media and Communications Officer, ARC Centre of Excellence in Exciton Science: (iain.strachan@unimelb.edu.au); +61 435 249 495
Image caption and credit
Image 1: A demonstration of optical effects made possible using the nanoscale assembly method to align gold nanorods within a material. Different colours become visible to the observer as the angle of the prototype device changes.
Credit: Heyou Zhang
Image 2: Heyou Zhang and collaborator Calum Kinnear working in the NanoScience Laboratory at The University of Melbourne's School of Chemistry.
Credit: Gavan Mitchell & Michelle Gough (University of Melbourne/Exciton Science).
Paper details
Direct Assembly of Vertically Oriented, Gold Nanorod Arrays
DOI: https://doi.org/10.1002/adfm.202006753
Journal: Advanced Functional Materials
Authors: Heyou Zhang1, Yawei Liu2, Muhammad Faris Shahin Shahidan3, Calum Kinnear4, Fatemeh Maasoumi1, Jasper Cadusch3, Eser Metin Akinoglu1, Timothy D. James5, Asaph Widmer-Cooper2,6, Ann Roberts3, and Paul Mulvaney1.
1: ARC Centre of Excellence in Exciton Science, School of Chemistry, University of Melbourne, Victoria 3010, Australia.
2: ARC Centre of Excellence in Exciton Science, School of Chemistry, University of Sydney, Sydney, NSW 2006, Australia.
3: ARC Centre of Excellence for Transformative Meta-Optical Systems, School of Physics, University of Melbourne, Victoria 3010, Australia.
4: CSIRO Manufacturing, Ian Wark Laboratories, Clayton, Victoria 3169, Australia.
5: Reserve Bank of Australia, Craigieburn, Victoria, Australia.
6: The University of Sydney Nano Institute, University of Sydney, Sydney, NSW 2006, Australia.
More about the ARC Centre of Excellence in Exciton Science:
The Centre of Excellence in Exciton Science is funded by the Australian Research Council to bring together researchers and industry to discover new ways to source and use energy. The Centre is a collaboration between Australian universities and international partners to research better ways to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. It works with industry partners to find innovative solutions for renewable energy in solar energy conversion, energy-efficient lighting and displays, security labelling and optical sensor platforms for defence. https://excitonscience.com/
Journal
Advanced Functional Materials