Scientists have fabricated tiny "nanopillars" capable of transmitting specific colors of light, at specific intensities, which hold promise for improved optical communication and anti-counterfeit measures for currency. For proof of concept, they decided to digitally reproduce Dutch master Johannes Vermeer's famous painting Girl With a Pearl Earring—just painted in light instead of pigment. They discussed their work in a recent paper published in the journal Optica.
“The quality of the reproduction, capturing the subtle color gradations and shadow details, is simply remarkable,” said co-author Amit Agrawal, a researcher with the National Institute of Science and Technology (NIST). “This work quite elegantly bridges the fields of art and nanotechnology.”
Nature abounds with examples of structural color. The bright colors in butterfly wings don't come from any pigment molecules but from how the wings are structured, for instance. The scales of chitin (a polysaccharide common to insects) are arranged like roof tiles. Essentially, they form a diffraction grating, except photonic crystals only produce certain colors, or wavelengths, of light while a diffraction grating will produce the entire spectrum, much like a prism
Scientists have sought to mimic nature with nanofabrication techniques capable of generating structural colors, just by tweaking the dimensions of nanostructures. However, the brightness of the colors such "metasurfaces" generate is fixed; they don't allow for tuning the brightness to achieve the complex interplay of light and shadow known in the art world as "chiaroscuro."
Nanopillars are a type of nanostructure with a unique shape, tapering from a bottom pillar into a pointed top. Group them into arrays and they are an excellent means of capturing light (up to 99 percent) with less material—making them a promising alternative for manufacturing solar panels. They can also be used to create antibacterial surfaces, much like the tiny, similarly shaped rods in a cicada's wings can kill bacteria by rupturing their cell membranes.
Nanopillars can also be used to generate structural colors. For instance, scientists have previously illuminated nanopillar arrays with white light to produce specific colors (red, blue, and green light), simply by varying the sizes (widths) of the nanopillars. However, the authors note that while those arrays can produce vibrant colors, the brightness (or intensity) of the generated colors is fixed and cannot be "tuned." Shifting levels of brightness are key to reproducing the chiaroscuro of an image. "By tuning the brightness of a color, the generated shadow rendering effect can make an image appear with a stronger space and stereo perception," the authors wrote.
It's possible to add liquid crystals and electrochromic polymers to metasurface arrays to control that brightness, but that control does not extend across the full visible spectral range. And the complicated electronic architectures required make it difficult to adapt such metasurfaces for practical applications.
The NIST team's nanopillars address many of those issues, most notably the question of tunability. The team fabricated titanium dioxide nanopillars on glass slides, using an elliptical cross-section rather than a circular one so that the diameter wasn't uniform but had a longer axis and shorter axis. By changing the alignment of the long axis with the polarization of incoming white ligRead More – Source
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