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Plasmonic Absorbers Capture Specific Wavelengths

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An experimental fabrication technique has created perfect absorbers for small bands of the electromagnetic spectrum from visible light through the near-infrared.

The technique could allow advanced thermal imaging systems to be produced more quickly and inexpensively and with higher sensitivity. It holds potential for a variety of other applications, such as masking heat signatures, and is easily scalable, can be applied to any surface geometry and costs less than current light-absorption technologies.

A scanning electron microscope image of silver nanocubes on a gold surface.
A scanning electron microscope image of silver nanocubes on a gold surface. Altering the size and number of the nanocubes tunes the material to absorb different wavelengths. Courtesy of Maiken Mikkelsen and Gleb Akselrod/Duke University.

The technique relies on plasmonics and was developed in the lab of professor Maiken H. Mikkelsen in the department of electrical and computer engineering and physics at Duke University.

To fabricate the absorbers, researchers first coated a surface with a thin film of gold. They then applied a layer of polymer a few nanometers thick, followed by a coating of silver cubes, each one about 100 nm in size. Dip-coating methods were used.

When light struck the engineered surface, a specific wavelength was trapped on the surface of the nanocubes in the form of plasmons and eventually dissipated into heat. By altering the thickness of the polymer film and the size and number of silver nanocubes, the coating could be tuned to absorb different wavelengths.

A curved object covered with the coating absorbs all red light, which leaves the object with a green tint.
A curved object covered with the coating absorbs all red light, which leaves the object with a green tint. A closer look reveals that the surface is covered with tiny 100-nm silver cubes. Courtesy of Maiken Mikkelsen and Gleb Akselrod/Duke University.

"The unique absorbing properties of the nanocubes can be predicted with straightforward formulas, making it easy to quickly determine recipes for surface coatings that provide desired spectral properties," said professor David R. Smith. "The nanocube system eliminates, or at least vastly reduces, cost and manufacturing issues, so that we can focus on impacting exciting application areas such as photovoltaics or thermal coatings."

By making the nanocubes larger to absorb wavelengths corresponding to thermal radiation, the technology could suppress or mask an object's natural thermal radiation, also known as blackbody radiation.

Coating photodetectors to absorb only specific wavelengths of IR light could enable novel and cheap cameras that could image portions of the IR spectrum. Among the researchers' next steps is to convert thermal radiation to an electrical signal.

The work was published in Advanced Materials (doi: 10.1002/adma.201503281).

Photonics Spectra
Jan 2016
A material engineered from artificial matter not found in nature. The artificial makeup and design of metamaterials give them intrinsic properties not common to conventional materials that are exploited as light waves and sound waves interact with them. One of the most active areas of research involving metamaterials currently explores materials with a negative refractive index. In optics, these negative refractive index materials show promise in the fabrication of lenses that can achieve...
Research & TechnologyDukeMaiken MikkelsenDavid SmithplasmonicsnanometamaterialcoatingsSensors & DetectorsTech Pulse

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