(December 15, 2010) — Rice University researchers say they have discovered a way to determine the temperature of a molecule or flowing electrons by using Raman spectroscopy combined with an optical antenna.

A new paper from the lab of Douglas Natelson, a Rice professor of physics and astronomy, details a technique that measures the temperature of molecules set between two gold nanowires and heated either by current applied to the wires or laser light. The paper was published this week in the online edition of Nature Nanotechnology.

Natelson, postdoctoral research associate Dan Ward and their colleagues found that while measuring heat at the nanoscale can be much more complicated than taking the temperature of macro objects, it can be done with a level of accuracy that will be of interest to the molecular electronics community or anyone who wants to know how heating and dissipation work at very small scales.

"When you get down to making small electronic devices or tiny junctions, you have to worry about how energy ends up in the form of heat," Natelson said. "In the case of macroscopic objects, like the filament in a light bulb, you can attach a thermocouple — a thermometer — and measure it." When light bulbs get hot, they also glow. "If you look at the spectrum of the light coming out, you can figure out how hot it is," he said.

Natelson and Ward are using this concept, though one can’t see the glow of a molecule. However, the researchers can send in light as a probe and detect the wavelength of the light that a molecule is returning when heated. "In Raman scattering, you send in light that interacts with your target. When it comes back, it will either have more energy than you put in, or the same, or less. And we can see that and figure out the effective temperature of whatever is scattering the light." 

The new work follows a paper published in September about the lab’s creation of nano antennas that concentrate and magnify light up to 1,000 times. That paper focused on the intensity of laser light shot into a gap between the tips of two gold nanowires.

This time, Natelson and Ward spread molecules — either oligophenylene vinylene or 1-dodecanethiol — on the surface of a gold nanowire and then broke the wire, leaving a nanoscale gap. When they were fortunate enough to find molecules in the gap — "the sweet spot" being where the metal wires are closest, Natelson said — they’d power up and read the resulting spectra.

The experiments were carried out in a vacuum with materials cooled to 80 kelvins (-315°F). The researchers found they could easily detect temperature fluctuations of up to 20 degrees in the molecules.

On the macro level, Natelson said, "You’re usually looking at something that’s essentially cold. You send in light, it dumps some of the energy into the thing you’re looking at and the light comes out with less energy than when you started. With Raman scattering, you can actually see particular molecular vibrational modes."

But the opposite can happen if the atoms are already vibrating with stored energy. "The light can grab some of that and come out with more energy than when it started," he explained.

The effect is most dramatic when current is supplied through the nanowires. "As we crank up the current through this junction, we can watch these different vibrations shaking more and more. We can watch this thing heat up."

Natelson said the experiments show not only how molecules wedged into the nanogap heat up, but also their interaction with the metal nanowires. "The vibrations show up as sharp peaks in the spectra," he said. "They have very definite energies. Underneath all that, there’s this sort of diffuse smear where the light instead is interacting with the electrons in the metal, the actual metal wires."

Natelson said it’s extremely hard to get direct information about how heating and dissipation work on nano scales. "In general, you can’t do it. There’s a lot of modeling, but in terms of experimental things you can actually measure that tell you what’s happening, everything is very indirect. This is an exception. This is special. You can see what’s happening.

"In our fantasy experiment, we’d say, ‘Boy, I wish I could go in with a thermometer,’ or, ‘I wish I could see each molecule and see how much it’s shaking.’ And this is effectively a way of doing that. We can really watch these things heat up."

Co-authors of the paper are James Tour, Rice’s T.T. and W.F. Chao Chair in Chemistry as well as a professor of mechanical engineering and materials science and of computer science, and former Rice chemistry graduate student David Corley. Read the abstract at: http://www.nature.com/nnano/journal/vaop/ncurrent/abs/nnano.2010.240.html

The Robert A. Welch Foundation and the Lockheed Martin Advanced Nanotechnology Center of Excellence at Rice supported the research. Located in Houston, Rice University is consistently ranked one of America’s best teaching and research universities.

Also read: 

• Nano antenna uses gold tips to gather laser light
• Gold nanoparticles induce luminescence in leaves 

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(December 14, 2010 – BUSINESS WIRE) — Nanostart AG (OTCQX: NASRY) is investing in Microlight Sensors Pte Ltd. Founded in 2006, Microlight Sensors develops, manufactures, and sells optical systems, instruments, and components for sensor technologies. Its roadmap includes exploitation of nanomaterials for ultrasensitive sensors.

Microlight Sensors’ current products make it possible to capture extremely low-intensity light and radiation near the wavelength range of infrared and visible light. They are deployed in civil security and monitoring purposes, across all illumination conditions of the 24hrs cycle without sensor damage. The instruments deliver equivalent daylight performance during night operations at conditions of extreme low light.

The company, which is headquartered in Singapore, possesses comprehensive expertise in optical engineering and design. In addition to current product lines, the company is also developing an entirely new generation of scanning optical equipment for imagery and spatial regeneration. The roadmap includes ultrasensitive sensor products based on nanomaterial technology.

Microlight Sensors targets the domestic security market in the Asia-Pacific region, which in 2007 was estimated to represent nearly 21% of the global market. By 2014, the market is anticipated to increase by 8.5% to 40 billion US dollars. The rapid growth forecast can in part be explained by growing civil security requirements and the prevalence of antiquated systems to be replaced.

The Nanostart investment will be directed toward new product developments as well as financing expansion of the company’s business, in particular sales and marketing in Asia.

Andreas Kröll, managing director of Nanostart Asia, describes the new investment: "Microlight Sensors currently possesses cutting-edge technology in an expanding market that is still being developed. We see above-average growth opportunities, which is why we decided to make this investment."

And Victor Teo, founder and CEO of Microlight adds: "We are convinced that we have found the right partner with Nanostart. The company possesses enormous commercialization expertise as well as the ability to facilitate further growth of Microlight through its international network."

Microlight is the third investment financed by the Nanostart Singapore Early Stage Venture Fund. Venture capital funds will be made available in tranches. The Nanostart fund takes an initial stake of 19%. Following distribution of the final tranche, the Nanostart fund will own shareholdings of 31% in Microlight Sensors.

Nanostart AG (OTCQX: NASRY) is a leading nanotechnology investment company, with portfolio companies spanning the globe from Silicon Valley to Singapore. The company provides venture capital financing for nanotechnology companies in various growth phases with a focus on innovation-driven industries of the future such as cleantech, life sciences and IT/electronics. For further information please visit www.nanostart.de and www.nanostart-asia.com.

Microlight Sensors designs, develops and assembles fully-integrated optical sensor and scanning systems for specialty applications in the homeland security and commercial spectral instrumentation systems market.

Disclaimer:
This notice constitutes neither an offer to sell nor a solicitation of offers to purchase or subscribe to securities. There will be no public offering of securities of Nanostart AG in conjunction with the existing listing of its shares in the "Entry Standard" segment of the regulated unofficial market (Freiverkehr) on the Frankfurt Stock Exchange. This notice does not constitute a securities prospectus. Neither this notice nor the information contained within is intended for direct or indirect distribution within Canada, Australia or Japan.

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