Their technique, which melts fibres along a chosen direction within a material, may lead to stronger, more resilient nanofibres and materials.
Physicists Jason Bochinski and Laura Clarke, with materials scientist Joe Tracy, placed specifically aligned gold nanorods within a solid material.
Gold nanorods absorb light at different wavelengths, depending upon the size and orientation of the nanorod, and then they convert that absorbed light directly into heat.
In this case, the nanorods were designed to respond to light wavelengths of 520 nanometres (nm) in a horizontal alignment and 800nm when vertically aligned.
When the different wavelengths of light were applied to the material, they melted the fibres along the chosen directions, while leaving surrounding fibres largely intact.
‘Being able to heat materials spatially in this way gives us the ability to manipulate very specific portions of these materials, because nanorods localize heat – that is, the heat they produce only affects the nanorod and its immediate surroundings,’ Tracy said in a statement.
According to Bochinski, the work also has implications for optimising materials that have already been manufactured.
‘We can use heat at the nanoscale to change mechanical characteristics of objects postproduction without affecting their physical properties, which means more efficiency and less waste.’
The researchers’ findings appear in Particle & Particle Systems Characterization.
The work was funded by grants from the National Science Foundation and Sigma Xi. Graduate students Wei-Chen Wu and Somsubhra Maity and former undergraduate student Krystian Kozek contributed to the work.
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