• Sandia National Laboratories researchers are ready to commercialize a nanoantenna-enabled detector on an assembled focal plane array for a thermal infrared camera. The gold nanoantennas are too small to be visible on top of the detector array.    Photo courtesy of Sandia National Laboratories
     Sandia National Laboratories researchers are ready to commercialize a nanoantenna-enabled detector on an assembled focal plane array for a thermal infrared camera. The gold nanoantennas are too small to be visible on top of the detector array. Photo courtesy of Sandia National Laboratories

Seeing Infrared with Sandia’s Nanoantennas

September 16, 2019
Posted by: George I. Seffers
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Researchers seek to transition a new detector design.  


Sandia National Laboratories researchers are ready to commercialize tiny, gold antennas to help cameras and sensors deliver clearer pictures of thermal infrared radiation for everything from stars and galaxies to people, buildings and items requiring security, lab officials announced today. In a Laboratory Directed Research and Development project, a team of researchers developed a nanoantenna-enabled detector that can boost the signal of a thermal infrared camera by up to 3 times and improve image quality by reducing dark current, a major component of image noise, by 10 to 100 times.

The traditional design of the detector that sits behind the camera lens or a sensor’s optical system seems to be reaching its performance limits, said David Peters, a Sandia manager and nanoantenna project lead. He said improved sensitivity in infrared detectors, beyond what the typical design can deliver, is important for both Sandia’s national security work and for other uses, such as astronomical research.

The sensitivity and image quality of an infrared detector usually depends on a thick layer of detector material that absorbs incoming heat and turns it into an electrical signal that can be collected and turned into an image. The thickness of the detector layer determines how much heat can be absorbed and read by the camera, but thick layers also have drawbacks. “The detector material is always spontaneously creating electrons that are collected and add noise to the image, which reduces image quality,” Peters said. “This phenomenon, called dark current, increases along with the thickness of the detector—the thicker the material is, the more noise in the image it creates.”

The research team developed a new design that breaks away from relying on thick layers and instead uses a subwavelength nanoantenna, a patterned array of gold square or cross shapes, to concentrate the light on a thinner layer of detector material. This design uses just a fraction of a micron of detector material, whereas traditional thermal infrared detectors have a thickness of 5 to 10 microns. A human hair is about 75 microns in width.

The nanoantenna-enhanced design helps detectors see more than 50 percent of an object’s infrared radiation while also reducing image distortion caused by dark current, whereas current technology can only see about 25 percent of infrared radiation. It also allows for the invention of new detector concepts that are not possible with existing technology.

“For example, with nanoantennas, it’s possible to dramatically expand the amount of information acquired in an image by exquisitely controlling the spectral response at the pixel level,” Peters said.

The team makes the nanoantenna-enabled detectors by slightly altering the usual process for making an infrared detector. It starts by “growing” the detector material on top of a thin disk called a wafer. Then the detector material is flipped onto a layer of electronics that read the signals collected by the nanoantenna and the detector layer. After discarding the wafer, a tiny amount of gold is applied to create the patterned nanoantenna layer on top of the detector material.

Sandia is pursuing leads to establish a Collaborative Research and Development Agreement to start transferring the technology to industry.

 

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