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Nov. 6, 2006 — Synova, the Lausanne, Switzerland, maker of water jet-guided laser technology, announced that it has signed a letter of intent to develop a joint venture with Sugino Machine Ltd. in Japan to bolster its presence and market share in the Japanese micromachining equipment market.

The letter outlines a 50/50 partnership between the two companies to form Sugino-Synova Ltd., and reflects Synova’s global expansion plans. The JV will complement Synova’s recent establishment of micromachining centers (MMCs) throughout the U.S., which aim to better serve the company’s current and prospective customers by efficiently and effectively providing localized application development and customer support.

Sugino-Synova Ltd. will provide manufacturing, development, sales and support services to Japanese customers. The JV will be located in Toyama, Japan in an industrial facility provided by Sugino, and is set to begin operations in January 2007 after closing on the agreement, which is slated for the end of this year. This announcement follows on the heels of MMC openings in the U.S.-Silicon Valley and Boston-that are set to open in January 2007.

Nov. 6, 2006 — Structured Materials Industries Inc. (SMI) announced that it has sold an oxide MOCVD system to China. The company did not name the customer.

The system will focus on ferroelectric oxide films, principally for non-volatile memory research and development. The tool is capable of depositing films of 8-inch or 6-inch diameter wafers. The company said the system is the first of its kind to be installed in China and is a cornerstone of SMI’s growing business base in Asia.

Nov. 6, 2006 — Purdue University’s Discovery Park has appointed Timothy Sands, the Basil S. Turner Professor of Engineering, as director of the Birck Nanotechnology Center.

The center opened in 2005 and is considered one of the best university facilities for nanotechnology research in the nation. The $58 million center — a two-floor, 187,000-square-foot facility — involves more than 300 faculty, staff and graduate students from 36 schools and departments across the university. Sands began his duties on Wednesday, Nov. 1.

Sands, who has been at Purdue since 2002, has a joint appointment between the School of Materials Engineering and the School of Electrical and Computer Engineering. He earned bachelor’s, master’s and doctorate degrees from the University of California, Berkeley, in 1980, 1981 and 1984, respectively. He was awarded the 1988 Robert Lansing Hardy Gold Medal from the Minerals, Metals and Materials Society and was elected to the Bohmische Physical Society in 1997. He received the Seed for Success Award from Purdue in 2005 and a National Science Foundation Research Initiation Award in 1994.

Sands said the prospect of Purdue building a center dedicated to nanotechnology research was a factor in his decision to come to the university.

Sands was director of the Integrated Materials Laboratory at Berkeley and director of the nonvolatile memory research group for Bell Communications Research (Bellcore) in Red Bank, N.J.

NanoSight launches LM20


November 6, 2006

Nov. 6, 2006 — NanoSight Ltd. of Salisbury, UK, announced the launch of its NANOSIGHT LM20, a bench-top system for rapid and easy sizing, and counting of individual nanoscale particles in suspension. The new system is intended to build on the success of the NANOSIGHT LM10 and includes precision mechanics and newly developed software that gives the non-microscope user the ability to easily analyze nanoparticles down to 15 nanometers, dependent on the material, in a matter of seconds.

The company says the system offers the ability to obtain higher resolution particle size distribution profiles than other more time-consuming and expensive methods, from samples with minimal sample pre-treatment (that is, dilution with a suitable solvent to an acceptable concentration range.) The NANOSIGHT LM20 uses a patented illumination method using a laser light source to visualize nanoscale particles on an individual basis moving under Brownian motion. The system instantly recognizes and quantifies polydisperse and multimodal samples as well as agglomerates and contaminants.

The company’s NanoSight Tracking Analysis analytical software package can directly and simultaneously measure the dynamic behavior and thus hydrodynamic size of each particle in a suspension and avoids the problems associated with the intensity bias to larger particles inherent in other bulk measurement dynamic light scattering techniques. The software enables real-time dynamic nanoparticle visualization from which independent quantitative estimation of particle size and size distribution can be obtained.

The system has been developed with customers to support research needs across industries. The system enables non-microscope users to quickly and accurately analyze nanoparticles in suspension and complements light scattering techniques such as photon correlation spectroscopy. Nanosight currently claims BASF, ICI, BP, Unilever and Roche as users of its tools.

Nov. 3. 2006 — Nantero Inc., a Woburn, Mass., company using carbon nanotubes for the development of next-generation semiconductor devices, announced it has resolved the major obstacles that had been preventing carbon nanotubes from being used in mass production in semiconductor fabs.

Nanotubes are widely acknowledged to hold great promise for the future of semiconductors, but most experts had predicted it would take a decade or two before they would become a viable material. This was due to several historic obstacles that prevented their use, including a previous inability to position them reliably across entire silicon wafers and contamination previously mixed with the nanotubes that made the nanotube material incompatible with semiconductor fabs.

Nantero announced it has developed a method for positioning carbon nanotubes reliably on a large scale by treating them as a fabric which can be deposited using methods such as spincoating, and then patterned using lithography and etching. The company said it has been issued patents on all the steps in the process, as well as on the article of the carbon nanotube fabric itself, US Patent No. 6,706,402, “Nanotube Films and Articles,” by the U.S. Patent and Trademark Office.

The patent relates to the article of a carbon nanotube film comprised of a conductive fabric of carbon nanotubes deposited on a surface. Nantero has also developed a method for purifying carbon nanotubes to the standards required for use in a production semiconductor fab, which means consistently containing less than 25 parts per billion of any metal contamination.

With these innovations, Nantero has become the first company in the world to introduce and use carbon nanotubes in mass production semiconductor fabs.

The company is developing NRAM — a high-density nonvolatile random access memory device intended for use as a universal memory. The company says it can be manufactured both as standalone devices and as embedded memory in application- specific devices such as ASICs and microcontrollers.

Nov. 3, 2006 — PI (Physik Instrumente) L.P., a manufacturer of nanopositioning and precision motion-control equipment for bio/nanotechnology, photonics, semiconductor and life science applications, announced the V-106 QuickScan series of PCI-card-driven, high-speed voice coil positioning stages, providing up to 20 mm (0.8 in.) of travel and resolution to 100 nanometers.

These closed-loop stages were designed for high-dynamics precision motion control applications, like those in biotechnology; laser beam control; scanning; optics & lens finishing; and fiber optics.

The stage is based on a frictionless, backlash-free, voice coil linear motor drive and a high-precision optical encoder featuring 100 nanometer resolution. The systems are designed to provide extremely smooth motion with velocities to 240 mm/s.

The company says the V-106 QuickScan stages achieve significantly higher dynamics than leadscrew-based units, with scanning frequencies to 20 Hz and above for small loads. It also claims another advantage of the frictionless voice coil drive is greater reliability and lifetime than screw-type drive mechanisms.

Nov. 2, 2006 — Grape Networks Inc., a San Ramon, Calif., developer of MEMS sensors and mesh networks for monitoring vineyards, announced that production systems for the monitoring of micro-climates for vineyards will be available in the first quarter of 2007. The Company also announced the expansion of its current system at Beringer Vineyards in Napa Valley.

The Climate Genie from Grape Networks consists of small battery powered nodes, often referred to as motes, to improve the yield and quality of crops. The Climate Genie wirelessly transmits temperature, humidity, and light information between each mote, with built-in radios, for monitoring anywhere in the world via the Internet. These motes/routers form a wireless mesh network with up to thousands of individual motes that are 10 to 300 meters apart. Each mote can sense a few simple things, such as temperature, moisture, light, or other physical qualities but as an aggregate gathers data about the quality and vitality of the grapes in the vineyard.

Nov. 1, 2006 — Vistec Lithography, a Cambridge, England, developer of electron beam lithography systems for the semiconductor industry, announced that it selected Grant Technologies, a designer and manufacturer of custom scientific and industrial solutions, to develop a refrigeration system to cool the lens, chamber and handling system within its VB300 electron beam nano-lithography machine.

Vistec Lithography’s VB300 electron beam system is designed for use in advanced production and R&D applications to create the ultra-fine images used in the semiconductor and nanotechnology industries. The system has the ability to load and fully expose substrates up to 300mm in diameter and mask plates up to 7 inches square with a lithographic capability to the sub-10nm level. These applications are undertaken by customers for the development of the next generations of nano-devices and structures, at major semiconductor manufacturers, industrial R&D facilities, as well as at universities and other technology centers of excellence.

When someone pronounces that their stockings have run, it is usually a bad thing. Not so for a select group of runners who lined up to race the Boston Marathon in April and the Chicago marathon in October.

For them, the socks they ran in may well have given them a slight performance boost. The company that makes the socks – Boston-based Greenyarn – claims they are the world’s most cushioned at a 200 needle count. They are manufactured using Eco-fabric, which is made from nanoparticles of bamboo-charcoal. Greenyarn says the nanoparticles help fight odor and germs, keep runners’ feet cool and dry, and help circulation.


Run faster, smell better, and look good too. Boston-based Greenyarn says its socks can help you do all three. Photo courtesy of Greenyarn
Click here to enlarge image

So not only will you allegedly run faster, but you’ll smell better while you do it. Far from being merely nano-enabled, the socks are designed with an archband and a Y-heel pocket for better fitting. This is intended to keep them from moving around in shoes and to help maintain an even cushion that will last an entire day – or a whole marathon.

Greenyarn says 10 runners tested the socks during the Boston Marathon earlier this year and said they experienced fewer blisters and a shorter recovery time after running the race. However, a control group wearing “placebo” socks was not part of the test, nor was a smell test conducted after the race to determine the efficacy of the nanoparticles.

More needs to be done to attract this burgeoning population to fill the growing number of high tech jobs

By Sarah Fister Gale

Hector Ruiz, chief executive officer of Advanced Micro Devices, is one of the most prominent Hispanic figures in high tech. Born in Piedras Negras, a small town in Mexico, he walked across the U.S.-Mexico border every day to attend a high school in Eagle Pass, Texas, from which he graduated as valedictorian just three years after beginning to learn English. Ruiz went on to earn a degree in electrical engineering from the University of Texas at Austin and a PhD from Rice University, before eventually becoming CEO of AMD.

But Ruiz is the exception in the U.S., where only a handful of Hispanics hold senior roles in scientific fields, academia and the high tech industry, and few students are finding their way into science degree programs, at community colleges or universities.

However, that fact is poised to change. The population of Hispanics is growing faster than any other minority group in the U.S. By the year 2010, nearly one out of every six Americans between the ages of eighteen and twenty-one will be Hispanic, and in many Western states, such as California, Hispanics will make-up nearly 50 percent of the working population, says Gus Koehler, president of Times Structures and co-author of “Training California’s New Workforce for 21st Century Nanotechnology, MEMS, and Advanced Manufacturing Jobs,” a survey prepared for the Economic and Workforce Development Program of California Community Colleges’ Workplace Learning Initiative.

Koehler points out that a huge number of high tech workers are beginning to retire, while new jobs in nanotech-related fields are being created daily as new products come to market.

“Who’s going to replace the retirees and fill those jobs?” Koehler asks. Hispanics.

Too often pigeon-holed into low-skill, low paying jobs, Hispanic students should represent the next wave of high tech engineers, operators and scientists – if schools can figure out how to draw them into the key fields in science, technology, engineering and math.

“There is a big educational gap,” notes Diana Rude, president of Bina Consulting, an economic development firm in Carmichael, Calif. She points to 2005 data on students in California that shows 58 percent of Hispanics in eighth grade scored below basic levels in math, and in 12th grade 70 percent scored below basic levels in science. “We are not doing a good job of educating these students.”

Rude also notes that the need to draw Hispanic kids into math and science is about more than helping them; it’s about helping the economy.

“This is a matter of having access to trained workers,” she says. “They will represent a majority of the workforce in 2010, and there is a strong economic link in California between educational attainment and increased investment and business development.”

Part of the challenge is that much of the population is not traditionally pushed toward science or math. If their English language skills are poor, Hispanic students may be redirected into remedial classes, or labeled as under-achievers when in fact they have all the skills and motivation to pursue deeper training.


An instructor and a student at Central New Mexico Community College examine a MEMS wafer together. Program proponents say the mentorship is critical in motivating students to enter technical fields. Photo courtesy of Central New Mexico Community College
Click here to enlarge image

Complicating matters further is that many Hispanics don’t recognize science and engineering as offering viable, good paying careers, says Juan de Pablo, professor of chemical and biological engineering at the University of Wisconsin – Madison, and the director of the Materials Science Research Center on Nanostructured Materials. “They have no role models at the scientist level or in the schools,” he says, noting that when it comes to drawing a generation into a new field of work, familiar role models are critical.

De Pablo, for one, is working to tackle these obstacles, through programs funded by grants from the state of Wisconsin and the National Science Foundation (NSF).

Through the PEOPLE program (Pre-college Enrichment Opportunity Program for Learning Excellence), which began in 1999, de Pablo works with teens who participate in three-week hands-on workshops where they learn about microelectronics and nanotechnology through activities such as dismantling and reassembling computers, touring cleanrooms, and measuring objects at the nanoscale.

“It’s exciting to watch their interest in science grow and to see them get drawn in,” de Pablo says.

He also works in partnership with the University of Puerto Rico to encourage graduate students to pursue PhDs at the University through grants from the National Science Foundation.

“Having Latinos achieve their PhDs and become prominent researchers in the U.S. is the first step in developing role models for younger students,” he says.

It’s already having an impact as several of his Ph.D. students mentor and teach the students in the PEOPLE workshops. “The kids get to see someone from a similar background, who speaks Spanish, getting a PhD in science, and that’s very effective,” he says.

Similar programs are underway across the country, where universities and community colleges are partnering with high schools to pique students’ interest in the sciences. But it’s a long battle that is far from over, says Matthias Pleil, a faculty member at Central New Mexico Community College in Albuquerque where more than 50 percent of the student population is Hispanic. Pleil is part of a group at CNM that runs MEMS Academy, a program sponsored by Sandia National Laboratories, that encourages middle and high school students to take advanced classes in science and math. “Getting high school students hooked on science is something we always struggle with.”

Pleil blames the elimination of labs and vocational training, at least in part, for the problem. “We need to do a better job of teaching science as an applied field.”