Tag Archives: Small Times Magazine

February 3, 2009: Researchers at Korea’s Ewha Womans University have developed a MEMS-based combination telescope and camera that can “instantly track and film events that occur without prior warning, according to a report in the Korea Herald.

Researcher Park Il-hung said the first-of-its kind MEMS system is capable of following the movements of superfast projectiles.

“If this equipment is placed on a space station, it has the capability to track light sources traveling at light speed on the Earth’s surface, while if it is placed on the ground, the telescope can successfully follow a bullet that is moving a meter away from the lens,” the scientist told the newspaper.

February 4, 2009: Infinite Power Solutions Inc., which develops and commercializes solid-state, rechargeable thin-film batteries, has sent out its first pre-production shipments of its new THINERGY micro-energy cell (MEC), the company announced in a news release.

MicroStrain and Lockheed Martin were among several companies to receive the MECs from IPS’s new manufacturing facility in Littleton, Colo., the release said.

Although often referred to in the industry as a thin-film battery, IPS’s thin-film micro-energy cells actually represent an entirely new class of energy storage device that combines a micro-thin, flexible form factor with unmatched rechargeability, cycle life and power performance, according to the company.

These component class devices enable many years of operation and are designed to last the life of the products they serve, eliminating the need for, and cost of, battery replacement.

“We believe micro-energy cells will help enable a new class of miniature, networked, autonomously powered mobile electronic devices that are perpetually recharged via ambient energy harvesting,” Macy Summers, Lockheed Martin, said in the release.

February 3, 2009: The shapes of some of the tiniest cellular structures are coming into sharper focus at the Howard Hughes Medical Institute’s Janelia Farm Research Campus, where scientists have developed a new imaging technology that produces the best three-dimensional resolution ever seen with an optical microscope.

With this new tool, scientists can pinpoint fluorescent labels in their images to within 10-20nm — about 10× the size of an average protein — in all three dimensions. The researchers say they now have an extremely powerful technology that will help reveal how biomolecules organize themselves into the structures and signaling complexes that drive cellular functions.

Their new method adds a third dimension to a cutting-edge form of light microscopy that scientists at Janelia Farm have used for the last two years to create two-dimensional images that pinpoint the location of fluorescently labeled proteins with extremely high resolution. To push this form of microscopy to the next level — three-dimensional imaging — the researchers borrowed a strategy widely used in industry to measure vanishingly small distances, such as the subtle variations in height on the surface of a computer chip.

Janelia Farm scientist Harald Hess and his colleagues adapted that technique, known as interferometry, to make it compatible with the fluorescent molecules often used by biologists to visualize proteins. When interferometry is combined with the super-high resolution photoactivated localization microscopy (PALM), researchers can see the three-dimensional architecture of cellular structures in extraordinary detail.

“This will be a good tool to really untangle things right down to the molecular structure level,” said Hess, who led the development of the new technology in the applied physics and instrumentation group at Janelia Farm.

Hess and collaborators at the National Institutes of Health, Florida State University, and Janelia Farm, who call their new tool interferometric photoactivated localization microscopy (iPALM), have already created detailed images of three-dimensional structures previously not resolvable with light microscopy. Their “photo gallery” includes images of the microtubules that give cells structure; the two layers of a cell’s outer membrane; and the focal adhesions that attach cells to their environment. Some of these images are included in a research article published in the February 2, 2009, issue of the Proceedings of the National Academy of Sciences describing the new technique.


The 3D distribution of membrane proteins within a cell revealed through iPALM imaging. The vertical position of fluorescently labeled VSVG proteins has been color coded, with red molecules being the deepest and purple the highest. (Image courtesy of Howard Hughes Medical Institute)

Rice rolls out new nanocars


February 2, 2009

February 2, 2009: This year’s model isn’t your father’s nanocar. It runs cool.

The drivers of Rice University’s nanocars were surprised to find modified versions of their creation have the ability to roll at room temperature. While practical applications for the tiny machines may be years away, the breakthrough suggests they’ll be easier to adapt to a wider range of uses than the originals, which had to be heated to 200°Celsius before they could move across a surface.

The nanocar was a sensation when introduced in 2005 by the lab of James Tour, Rice’s Chao Professor of Chemistry and a professor of mechanical engineering and materials science and computer science.

Tour’s original single-molecule car had buckyball wheels and flexible axles, and it served as a proof-of-concept for the manufacture of machines at the nanoscale. A light-activated paddlewheel motor was later attached to propel it, and the wheels were changed from buckyballs to carboranes. These were easier to synthesize and permitted the motor to move, because the buckyball wheels trapped the light energy that served as fuel before the motor could turn. Since then, nanotrucks, nanobackhoes and other models have been added to the Rice showroom.

A large-scale representation of the nanocar made its public debut in Houston’s famous Art Car Parade last year.

Rice’s Stephan Link, an assistant professor of chemistry who specializes in plasmonics, took the wheel for a new series of experiments that built upon Tour’s pioneering work. Link’s primary achievement was using single-molecule fluorescence imaging to track the tiny vehicles, as opposed to the scanning tunneling microscopy (STM) used in earlier experiments. STM imaging can capture matter at an atomic scale, but the technique requires the target to be on a conductive substrate. Not so with fluorescent imaging.

A paper on the new research was published this month in ACS Nano was authored by Link; Tour; Anatoly Kolomeisky, associate professor of chemistry and chemical and biomolecular engineering; postdoc Guillaume Vives; graduate students Saumyakanti Khatua and Jason M. Guerrero; and undergraduate Kevin Claytor.

“We thought, ‘We’re just going to take an image, and nothing’s going to happen,'” said Link of the team’s initial success in attaching fluorescent dye trailers to the nanocars. “We were worrying about how to build a temperature stage around it and how to heat it and how to make it move.

“To my surprise, my students came back and said, ‘They moved!'”

Sure enough, time-lapsed films monitoring an area 10×10μm square showed the cars, which appear as fluorescing dots, zigging and zagging on a standard glass slide. Link said the cars moved an average 4.1nm (or two nanocar lengths) per second.

“It took us another year to quantify it,” said Link, noting as key the development of a new tracking algorithm by Claytor that will be the subject of a future paper.

The simplest technique for finding moving nanocars was precisely the way astronomers find distant cosmic bodies — Look at a series of images, and the dots that move are winners. The ones that don’t are either fluorescing molecules sitting by themselves or nanocars stuck in park.

The dye — tetramethylrhodamine isothiocyanate — had the added attraction of emitting a polarized signal. Since dye molecules tended to line up with the chassis, the researchers could always tell which way the cars were pointed.

Link hoped cars with dye embedded into the chassis can be built that would eliminate the drag created by the fluorescent trailer. He speculated that putting six wheels instead of four on a nanocar could also help keep it moving in one direction, much like a tank with treads.

“Now that we see movement, the challenge is to take it to the next level and make it go from point A to point B. That’s not going to be easy.” Creating nanotracks or roads may be part of the solution, Link said.

All the research is directed at the ultimate goal of building machines from the bottom up in much the same way proteins are built to carry out tasks in nature.

“In terms of computing, having these single molecules be addressable is a goal everybody wants to reach,” said Link. “And to understand and emulate biophysics and biomechanics, to build a device based on what nature gives us, is of course one of the dreams of nanotechnology.”

January 30, 2009: Mike Splinter, CEO of nanomanufacturing company Applied Materials Inc., was one of several business leaders who met with President Barak Obama this week to urge quick action on a plan to stimulate the US economy.

Splinter, whose company produces a line of nanomanufactured thin films for solar panels, said that government incentives and support for solar technology is key in Obama’s mission to strengthen the US infrastructure — just as important as repairing bridges and roads.

Splinter urged the president and Congress to act in three specific ways on solar energy:

  • Provide for short-term refundability of the federal solar investment tax credit as well as new tax incentives to locate solar manufacturing facilities in the United States.
  • Require the adoption of renewable and solar energy sources for federal properties, make $10 billion available for construction and operation of solar installations and increase the Energy Department’s solar technologies budget to $300 million.
  • Create a “clean energy bank” that would provide low- or no-cost financing for solar and other renewable-energy projects.

“We talked about what was good, what was bad” in the stimulus package, Splinter said in a telephone interview with Bloomberg. “Most everybody represented a different part of the industrial landscape of the U.S., so it was quite comprehensive.”

Applied Materials’ SunFab thin film manufacturing line, announced in 2007, is designed to produce enough solar modules in a year to generate up to 75 megawatts of electrical power, according to the company. SunFab, the company has said, promises to reduct the cost of utility-scale and building-integrated photovoltaic system installations by more than 20 percent.

In a statement issued in a news release after the meeting, Splinter praised Obama’s “great leadership in energy.”

“The president’s objective to reduce reliance on fossil fuels by harnessing the power of the sun can be realized through solar technology and products that we are innovating and manufacturing here in this country,” Splinter said in the statement. “This could create thousands of new jobs and ultimately change the global energy equation.”

January 29, 2009: Bayer MaterialScience is building a new facility in Germany that could churn out up to 200 tons of carbon nanotubes a year, making it the largest nanotube factory in the world, according to a company news release.

The company said it will invest around $29 million on the project, which should create about 20 jobs.

“We are investing in a key technology of the future that will open up a broad range of new applications for us,” said Bayer AG board member Wolfgang Plischke. According to the company, the global market for carbon nanotubes will grow by 25% a year. In 10 years, Bayer said, annual carbon nanotube sales are expected to reach $2 billion.

In December, the US Environmental Protection Agency gave Bayer MaterialScience regulatory approval to sell its multiwall carbon nanotubes — what it calls Baytubes — in the United States. The approval covered Baytubes C 150 P and HP grades, produced in a plant in Laufenburg, Germany with an annual capacity of 60 metric tons.

Baytubes can be added to polymer matrices or metal systems as a modifier or filler to improve their mechanical strength and/or antistatic properties, and are already used in epoxy, thermoplastic and coating systems, according to the company.


Bayer board member Wolfgang Plischke and German research minister Thomas Rachel pose with a model and a sample of carbon nanotubes. (Photo courtesy of Bayer MaterialScience)

January 28, 2009: Illumina Inc. is supplying the “DNA microarray inside” for a deal between personal genetics company 23andMe Inc. and Swiss research company mondoBIOTECH AG announced at the World Economic Forum in Davos, Switzerland.

23andMe and mondoBIOTECH will work together to facilitate research of the genetic bases of rare and potentially fatal diseases, such as pulmonary arterial hypertension, sarcoidosis and pulmonary fibrosis, the genetics of which are poorly understood. According to a news release, mondoBIOTECH will identify individuals suffering from certain rare diseases and sponsor their enrollment in the 23andMe Personal Genome Service.

Researchers then will be able to study the genetic information collected, along with any phenotypic information provided, in clinical trials, to understand potential causes of these diseases. 23andMe will coordinate genome-wide association studies for mondoBIOTECH affiliates using its research infrastructure and bioinformatics expertise.

The Illumina DNA microarray analysis technology used by 23andMe enables the company to identify some custom markers. This feature helped the company select SNPs (single nucleotide polymorphisms), or variants that provide coverage of genes associated with drug response — information that is proving to be critical for the development of personalized medicine. In addition to having over half a million markers available for disease research, these “pharmacogenetic” indicators included in the 23andMe dataset could provide invaluable information for identifying treatment protocols, according to the release.

January 28, 2009: Single-atom quantum dots created by researchers at Canada’s National Institute for Nanotechnology and the University of Alberta make possible a new level of control over individual electrons, a development that suddenly brings quantum dot-based devices within reach. Composed of a single atom of silicon and measuring less than one nanometer in diameter, these are the smallest quantum dots ever created.

Quantum dots have extraordinary electronic properties, like the ability to bottle-up normally slippery and speedy electrons, that allow controlled interactions among electrons to be put to use to do computations. Until now, quantum dots have been usable only at impractically low temperatures, but the new atom-sized quantum dots perform at room temperature.

Often referred to as artificial atoms, quantum dots have previously ranged in size from 2-10nm in diameter. While typically composed of several thousand atoms, all the atoms pool their electrons to “sing with one voice,” that is, the electrons are shared and coordinated as if there is only one atomic nucleus at the center. That property enables numerous revolutionary schemes for electronic devices.

Research project leader Robert A. Wolkow described the potential impact saying, “Because they operate at room temperature and exist on the familiar silicon crystals used today’s computers, we expect these single atom quantum dots will transform theoretical plans into real devices.”

The single atom quantum dots have also demonstrated another advantage – significant control over individual electrons by using very little energy. Wolkow sees this low energy control as the key to quantum dot application in entirely new forms of silicon-based electronic devices, such as ultra low power computers. “The capacity to compose these quantum dots on silicon, the most established electronic material, and to achieve control over electron placement among dots at room temperature puts new kinds of extremely low energy computation devices within reach.”

Results of the work were posted Jan. 27 in the online edition and published in the Jan. 30 edition of Physical Review Letters.


Four atomic quantum dots are coupled to form a “cell” for containing electrons. The cell is filled with just two electrons. Control charges are placed along a diagonal to direct the two electrons to reside at just two of the four quantum dots comprising the cell. This new level of control of electrons points to new computation schemes that require extremely low power to operate. Such a device is expected to require about 1,000× less power and will be about 1,000× smaller than today’s transistors. (Credit: Robert A. Wolkow)

January 28, 2009: CETR has released its next-generation Apex nanomechanical test instrument, the company announced in a news release.

Apex comes with two interchangeable modules: Nano indenter (NH-3) and Micro indenter (MH-2), which can easily be interchanged, the company said. Both modules can be used to indent or scratch the material as well as wear and friction at nano- and microscales.

Apex was designed for use with thin-films, PVD & CVD coatings, microelectronics, solar cells, MEMS, and other applications.

January 27, 2009: Miami-based Radiation Shield Technologies has been granted a US patent that secures its rights to the nanotech inside the company’s proprietary Demron protective material, according to a company news release.

Patent No. 7,476,889, “Radiation Detectable and Protective Articles” covers the company’s suits made to withstand chemical, biological, radiological and nuclear incidents, the news release said.

Demron contains what the company calls an “advanced radiopaque nanopolymeric compound” fused between layers of fabric and manufactured into lightweight nuclear-radiation blocking garments including full-body suits, vests, blankets and medical X-ray vests and aprons.


Demron full body suit. (Photo courtesy of Business Wire)