Making colours out of gold and DNA
Folk belief says there鈥檚 a pot of gold at the end of the rainbow, but a new technology is turning that idea on its head 鈥 using particles of gold to make colours. With further work, the method developed at Aalto University could herald a new display technology.
The technique uses gold nanocylinders suspended in a gel. The gel only transmits certain colours when lit by polarized light, and the colour depends on the orientation of the gold nanocylinders. In a clever twist, a collaboration led by Anton Kuzyk鈥檚 and Juho Pokki鈥檚 research groups used DNA molecules to control the orientation of gold nanocylinders in the gel.
鈥楧NA isn鈥檛 just an information carrier 鈥 it can also be a building block. We designed the DNA molecules to have a certain melting temperature, so we could basically program the material,鈥 says Aalto doctoral candidate Joonas Ryssy, the study鈥檚 lead author. When the gel heats past the melting temperature, the DNA molecules loosen their grip and the gold nanocylinders change orientation. When the temperature drops, they tighten up again, and the nanoparticles go back to their original position.
The team tested several custom DNA molecules with different melting temperatures to find the best response. With the current system, the technology can produce red and green light. Once further work makes blue light transmission possible, this approach could be used to generate any colour by mixing red, green, and blue.
鈥楾he whole concept 鈥 the underlying philosophy behind the work 鈥 is to use simple methods, simple materials and simple tools to generate colours in a dynamic and reversible way,鈥 says Sesha Manuguri, a postdoctoral researcher at Aalto who led the study.
For Manuguri, part of the elegance of the technique is that the gold nanocylinders accomplish both the necessary tasks. 鈥楾he gold nanorods get hot when they鈥檙e lit, heating the gel, and they鈥檙e also responsible for colour formation. So, you don鈥檛 need separate heating elements,鈥 he says.
With further development, this approach could be used to produce colour in different kinds of displays. Because the materials are all biocompatible, this could be ideal for displays on wearable sensor devices, but the technology could also be used in billboards or other displays.
鈥榃e鈥檝e done the basic science to bring these building blocks together in a symbiotic manner to create something functional. Now it鈥檚 up to engineers to explore what kind of devices could be made,鈥 says Manuguri.
Further Information
The full paper is available in .
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