Innovations in satellite imaging, facial and movement recognition and GPS location systems, among many other forms of tech including DNA barcoding, will converge to deem RFID an obsolete memory. The latest in nanotech imaging is documented in the story below.
FROM GIZMAG
Next-gen nanotech spy satellites will count the hairs on your head
Anyone who likes to get their gear off for a spot of naked sunbathing in the backyard may have to think twice in the future. Researchers have developed a new nanotechnology-based “microlens” that could lead to a new generation of ultra-powerful satellite cameras and night-vision devices. Thankfully, the new lens is used for infrared imaging, so the technology is more likely to be used for security and monitoring climate change and deforestation than spying on naturists boosting their vitamin D levels.
Developed by researchers at Rensselaer Polytechnic Institute, the lens uses gold to boost the strength of infrared imaging. By leveraging the unique properties of nanoscale gold to “squeeze” light into tiny holes in the surface of the device, the researchers have doubled the detection cabability of a quantum dot-based infrared detector. With some refinements, the researchers expect this new technology should be able to enhance this by up to 20 times.
According to project leader Shawn-Yu Lin, professor of physics at Rensselaer, the breakthrough is the first in more than a decade to demonstrate success in enhancing the signal of an infrared detector without also increasing the noise.
“Infrared detection is a big priority right now, as more effective infrared satellite imaging technology holds the potential to benefit everything from homeland security to monitoring climate change and deforestation,” said Lin.
“We have shown that you can use nanoscopic gold to focus the light entering an infrared detector, which in turn enhances the absorption of photons and also enhances the capacity of the embedded quantum dots to convert those photons into electrons. This kind of behavior has never been seen before,” he said.
The detectivity of an infrared photodetector is determined by how much signal it receives, divided by the noise it receives. The current state-of-the art in photodetectors is based on mercury-cadmium-telluride (MCT) technology, which has a strong signal but faces several challenges including long exposure times for low-signal imaging. Lin said his new study creates a roadmap for developing quantum dot infrared photodetectors (QDIP) that can outperform MCTs, and bridge the innovation gap that has stunted the progress of infrared technology over the past decade.
The surface plasmon QDIPs are long, flat structures with countless tiny holes on the surface. The solid surface of the structure that Lin built is covered with about 50 nanometers – or 50 billionths of a meter – of gold. Each hole is about 1.6 microns – or 1.6 millionths of a meter – in diameter, and 1 micron deep. The holes are filled with quantum dots, which are nanoscale crystals with unique optical and semiconductor properties.
The interesting properties of the QDIP’s gold surface help to focus incoming light directly into the microscale holes and effectively concentrate that light in the pool of quantum dots. This concentration strengthens the interaction between the trapped light and the quantum dots, and in turn strengthens the dots’ ability to convert those photons into electrons. The end result is that Lin’s device creates an electric field up to 400 percent stronger than the raw energy that enters the QDIP.
READ MORE
FROM GIZMAG
Next-gen nanotech spy satellites will count the hairs on your head
Anyone who likes to get their gear off for a spot of naked sunbathing in the backyard may have to think twice in the future. Researchers have developed a new nanotechnology-based “microlens” that could lead to a new generation of ultra-powerful satellite cameras and night-vision devices. Thankfully, the new lens is used for infrared imaging, so the technology is more likely to be used for security and monitoring climate change and deforestation than spying on naturists boosting their vitamin D levels.
Developed by researchers at Rensselaer Polytechnic Institute, the lens uses gold to boost the strength of infrared imaging. By leveraging the unique properties of nanoscale gold to “squeeze” light into tiny holes in the surface of the device, the researchers have doubled the detection cabability of a quantum dot-based infrared detector. With some refinements, the researchers expect this new technology should be able to enhance this by up to 20 times.
According to project leader Shawn-Yu Lin, professor of physics at Rensselaer, the breakthrough is the first in more than a decade to demonstrate success in enhancing the signal of an infrared detector without also increasing the noise.
“Infrared detection is a big priority right now, as more effective infrared satellite imaging technology holds the potential to benefit everything from homeland security to monitoring climate change and deforestation,” said Lin.
“We have shown that you can use nanoscopic gold to focus the light entering an infrared detector, which in turn enhances the absorption of photons and also enhances the capacity of the embedded quantum dots to convert those photons into electrons. This kind of behavior has never been seen before,” he said.
The detectivity of an infrared photodetector is determined by how much signal it receives, divided by the noise it receives. The current state-of-the art in photodetectors is based on mercury-cadmium-telluride (MCT) technology, which has a strong signal but faces several challenges including long exposure times for low-signal imaging. Lin said his new study creates a roadmap for developing quantum dot infrared photodetectors (QDIP) that can outperform MCTs, and bridge the innovation gap that has stunted the progress of infrared technology over the past decade.
The surface plasmon QDIPs are long, flat structures with countless tiny holes on the surface. The solid surface of the structure that Lin built is covered with about 50 nanometers – or 50 billionths of a meter – of gold. Each hole is about 1.6 microns – or 1.6 millionths of a meter – in diameter, and 1 micron deep. The holes are filled with quantum dots, which are nanoscale crystals with unique optical and semiconductor properties.
The interesting properties of the QDIP’s gold surface help to focus incoming light directly into the microscale holes and effectively concentrate that light in the pool of quantum dots. This concentration strengthens the interaction between the trapped light and the quantum dots, and in turn strengthens the dots’ ability to convert those photons into electrons. The end result is that Lin’s device creates an electric field up to 400 percent stronger than the raw energy that enters the QDIP.
READ MORE
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