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Nano-sized Electronic Circuit Promises Bright View of Early Universe
July 11, 2008A newly developed nano-sized electronic device is an important step toward helping astronomers see invisible light dating from the creation of the universe. This invisible light makes up 98% of the light emitted since the "big bang," and may provide insights into the earliest stages of star and galaxy formation almost 14 billion years ago.
The tiny, new circuit, developed by physicsts at Rutgers University, NASA's Jet Propulsion Laboratory in Pasadena, Calif., and the State University of New York at Buffalo, is 100 times smaller than the thickness of a human hair. It is sensitive to faint traces of light in the far-infrared spectrum (longest of the infrared wavelengths), well beyond the colors humans see.
"In the expanding universe, the earliest stars move away from us at a speed approaching the speed of light," said Michael Gershenson, professor of physics at Rutgers and one of the lead investigators. "As a result, their light is strongly red-shifted when it reaches us, appearing infrared."
Because the Earth's atmosphere strongly absorbs far-infrared light, Earth-based radiotelescopes cannot detect the very faint light emitted by these stars. So scientists are proposing a new generation of space telescopes to gather this light. Yet to take full advantage of space-borne telescopes, detectors that capture the light will have to be far more sensitive than any that exist today.
Detectors of infrared and submillimeter waves, known as bolometers, measure the heat generated when they absorb photons, or units of light. Today's infrared bolometer technology is mature and has reached the limit of its performance.
"The device we built, which we call a hot-electron nanobolometer, is potentially 100 times more sensitive than existing bolometers," Gershenson said. "It is also faster to react to the light that hits it."
The research team is publishing a description of the experimental device in an upcoming issue of the journal Nature Nanotechnology. The journal's website posted an electronic copy of the paper this week at: http://dx.doi.org/10.1038/nnano.2008.173. The team is led by Gershenson and Boris Karasik of the Jet Propulsion Laboratory (JPL), a NASA center managed by the California Institute of Technology (CalTech). Most of the fabrication and measurement work was done at Rutgers by graduate student Jian Wei, now a post-doctoral associate at the Northwestern University; postdoctoral researcher David Olaya, now with the National Institute of Standards and Technology; and postdoctoral researcher Sergey Pereverzev, now with JPL and CalTech. The theoretical support for this research was provided by Andrei Sergeev of the State University of New York at Buffalo.
Made of titanium and niobium metals, the novel device is about 500 nanometers long and 100 nanometers wide. The physicists built it using thin-film and nanolithography techniques similar to those used in computer chip fabrication. The device operates at very cold temperatures - about 459 degrees below zero Fahrenheit, or one-tenth of one degree above absolute zero on the Kelvin scale.
Photons striking the nanodetector heat electrons in the titanium section, which is thermally isolated from the environment by superconducting niobium leads. By detecting the infinitesimal amount of heat generated in the titanium section, one can measure the light energy absorbed by the detector. The device can detect as little as a single photon of far infrared light.
"With this single detector, we have demonstrated a proof of concept," said Gershenson. "The final goal is to build and test an array of 100 by 100 photodetectors, which is a very difficult engineering job." Rutgers took the lead on fabrication and electrical characterization of the single detector, and JPL will take the lead on the optical characterization of the detector and developing detector arrays.
Gershenson expects the detector technology to be useful for exploring the early universe when satellite-based far-infrared telescopes start flying 10 to 20 years from now. "That will make our new technology useful for examining stars and star clusters at the farthest reaches of the universe," he said.
Rutgers, The State University of New Jersey
Because the Earth's atmosphere strongly absorbs far-infrared light, Earth-based radiotelescopes cannot detect the very faint light emitted by these stars. So scientists are proposing a new generation of space telescopes to gather this light. Yet to take full advantage of space-borne telescopes, detectors that capture the light will have to be far more sensitive than any that exist today.
Detectors of infrared and submillimeter waves, known as bolometers, measure the heat generated when they absorb photons, or units of light. Today's infrared bolometer technology is mature and has reached the limit of its performance.
"The device we built, which we call a hot-electron nanobolometer, is potentially 100 times more sensitive than existing bolometers," Gershenson said. "It is also faster to react to the light that hits it."
The research team is publishing a description of the experimental device in an upcoming issue of the journal Nature Nanotechnology. The journal's website posted an electronic copy of the paper this week at: http://dx.doi.org/10.1038/nnano.2008.173. The team is led by Gershenson and Boris Karasik of the Jet Propulsion Laboratory (JPL), a NASA center managed by the California Institute of Technology (CalTech). Most of the fabrication and measurement work was done at Rutgers by graduate student Jian Wei, now a post-doctoral associate at the Northwestern University; postdoctoral researcher David Olaya, now with the National Institute of Standards and Technology; and postdoctoral researcher Sergey Pereverzev, now with JPL and CalTech. The theoretical support for this research was provided by Andrei Sergeev of the State University of New York at Buffalo.
Made of titanium and niobium metals, the novel device is about 500 nanometers long and 100 nanometers wide. The physicists built it using thin-film and nanolithography techniques similar to those used in computer chip fabrication. The device operates at very cold temperatures - about 459 degrees below zero Fahrenheit, or one-tenth of one degree above absolute zero on the Kelvin scale.
Photons striking the nanodetector heat electrons in the titanium section, which is thermally isolated from the environment by superconducting niobium leads. By detecting the infinitesimal amount of heat generated in the titanium section, one can measure the light energy absorbed by the detector. The device can detect as little as a single photon of far infrared light.
"With this single detector, we have demonstrated a proof of concept," said Gershenson. "The final goal is to build and test an array of 100 by 100 photodetectors, which is a very difficult engineering job." Rutgers took the lead on fabrication and electrical characterization of the single detector, and JPL will take the lead on the optical characterization of the detector and developing detector arrays.
Gershenson expects the detector technology to be useful for exploring the early universe when satellite-based far-infrared telescopes start flying 10 to 20 years from now. "That will make our new technology useful for examining stars and star clusters at the farthest reaches of the universe," he said.
Rutgers, The State University of New Jersey
Harvard University engineers demonstrate quantum cascade laser nanoantenna
In a major feat of nanotechnology engineering researchers from Harvard University have demonstrated a laser with a wide-range of potential applications in chemistry, biology and medicine.
Researchers approach quantum limit in third-order nonlinear light-light interaction
Researchers from Lehigh University and the Swiss Federal Institute of Technology in Zurich (ETH) have reported unprecedented nonlinear optical efficiency in some small organic molecules that makes the molecules potentially useful for optical computing, optical data processing, and optical telecommunication.
The 2002 Nobel Prize in Physics
The Royal Swedish Academy of Sciences has decided to award the Nobel Prize in Physics for 2002 with one half jointly to Raymond Davis Jr Department of Physics and Astronomy, University of Pennsylvania, Philadelphia, USA, and Masatoshi Koshiba International Center for Elementary Particle Physics, University of Tokyo, Japan "for pioneering contributions to astrophysics, in particular for the detection of cosmic neutrinos" and the other half to Riccardo Giacconi Associated Universities Inc., Washington DC, USA "for pioneering contributions to astrophysics, which have led to the discovery of cosmic X-ray sources". Two New Windows on the Universe The Earth lies in the path of
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