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(July 9, 2010) — Metallic carbon nanotubes (CNT) show great promise for applications from microelectronics to power lines because of their ballistic transmission of electrons. But magnets can stop those electrons in their tracks.

Rice physicist Junichiro Kono and his team have been studying the Aharonov-Bohm effect — the interaction between electrically charged particles and magnetic fields — and how it relates to carbon nanotubes. While doing so, they came to the unexpected conclusion that magnetic fields can turn highly conductive nanotubes into semiconductors.

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Their findings are published online this month in Physical Review Letters.

"When you apply a magnetic field, a band gap opens up and it becomes an insulator," said Kono, a Rice professor in electrical and computer engineering and in physics and astronomy. "You are changing a conductor into a semiconductor, and you can switch between the two. So this experiment explores both an important aspect of the results of the Aharonov-Bohm effect and the novel magnetic properties of CNTs."

Kono, graduate student Thomas Searles, and their colleagues at the National Institute of Standards and Technology (NIST) and in Japan successfully measured the magnetic susceptibility of a variety of nanotubes for the first time; they confirmed that metallics are far more susceptible to magnetic fields than semiconducting nanotubes, depending upon the orientation and strength of the field.

Single-walled nanotubes (SWNTs) — rolled-up sheets of graphene — would all look the same to the naked eye if one could see them. But a closer look reveals nanotubes come in many forms, chiralities, depending on how they’re rolled. Some are semiconducting; some are highly conductive metallics. The gold standard for conductivity is the armchair nanotube, so-called because the open ends form a pattern that looks like armchairs.

Kono and Searles traveled to the Tsukuba Magnet Laboratory at the National Institute for Materials Science (NIMS) in Japan, where the world’s second-largest electromagnet was used to tease a refined ensemble of 10 chiralities of SWNTs, some metallic and some semiconducting, into giving up their secrets.

By ramping the big magnet up to 35 tesla, they found that the nanotubes would begin to align themselves in parallel and that the metallics reacted far more strongly than the semiconductors. (For comparison, the average MRI machine for medical imaging has electromagnets rated at 0.5 to 3 tesla.) Spectroscopic analysis confirmed the metallics, particularly armchair nanotubes, were two to four times more susceptible to the magnetic field than semiconductors and that each chirality reacted differently.

The nanotubes were all about 0.7 to 0.8 nanometers (or billionths of a meter) wide and 500 nanometers long, so variations in size were not a factor in results by Searles. He spent a week last fall running experiments at the Tsukuba facility’s "hybrid," a large-bore superconducting magnet that contains a water-cooled resistive magnet.

Kono said the work would continue on purified batches of nanotubes produced by ultracentrifugation at Rice. That should yield more specific information about their susceptibility to magnetic fields, though he suspects the effect should be even stronger in longer metallics. "This work clearly shows that metallic tubes and semiconducting tubes are different, but now that we have metallic-enriched samples, we can compare different chiralities within the metallic family," he said.

Co-authors of the paper include Yasutaka Imanaka and Tadashi Takamasu of NIMS, Tsukuba, Japan; Hiroshi Ajiki of the Photon Pioneers Center at Osaka University, Japan; and Jeffrey Fagan and Erik Hobbie, researchers at NIST, Gaithersburg, Md.

Searles conducted the majority of the research during a visit to NIMS supported in part by a National Science Foundation Partnerships for International Research and Education grant to Kono and his co-principal investigators. Other funding came from the Department of Energy Office of Basic Energy Sciences, the Robert A. Welch Foundation and the Grant-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science and Technology of Japan.

Read the abstract here: http://prl.aps.org/abstract/PRL/v105/i1/e017403

Read more about semiconductors here

Read more about carbon nanotubes here

(July 8, 2010) — The FlexTech Alliance awarded a contract to the Western Michigan University (WMU) to create a user-friendly database for accessing technical information on functional materials for electronic display and flexible printed electronics.

The registry targets more timely, efficient, and accurate selection of the most appropriate material sets for flexible, printed electronics industry product developments, and serve all manufacturing platforms. The project is being funded in response to an identified critical industry need for more reliable performance and applications data on the variety of materials used in flexible, printed and organic (FPO) electronics applications. FlexTech’s quarterly workshops provided the forum to bring together industry experts to formulate and outline the initial needs behind this project.

Benefits to new materials developers and suppliers for contributing to the registry include:

  • increased access to technical product information,
  • greater visibility within the flexible electronics supply chain,
  • a broadened customer base,
  • and the listing of company products along with emerging competitor products in the industry.

Open access to this information will enable industrial and university communities to propagate the use of printed electronic technology. The Center for the Advancement of Printed Electronics (CAPE) at WMU is positioned to create this registry because of its dedication to developing printing as a low cost means for manufacturing electronic devices.

“Western Michigan University is honored to take on the task of creating this much needed registry of materials for the constituents of the printed electronics industry,” said Erika Hrehorova, Assistant Professor at WMU’s CAPE. “The supply chain is expanding for this developing industry and there are already a significant number of materials suppliers ranging from small start-ups to large corporations offering products to service the industry. With this project, we will consolidate available information about functional materials into a searchable database to assist technology developers and manufacturers to commercialize and grow their technologies.”

"FlexTech is pleased to award WMU a contract for the materials registry," stated Michael Ciesinski, chief executive officer for the FlexTech Alliance. "The creation of a searchable, web-accessible materials and process registry, segmented by functional types (e.g., conductors, semiconductors, dielectrics, substrates, barrier materials) and by manufacturing platforms (e.g., roll-to-roll, gravure, inkjet) will become an essential industry tool."

Entries to the database will include relevant non-proprietary information about the material itself (e.g., viscosity, electrical and optical properties, particle loading levels, formulation), information on processing (by manufacturing platform), information on curing conditions, and any special information that might be relevant for a given end application. Each entry will also specify the analytical methods used for data collection of the material’s properties.

“Michigan has long been a leader in manufacturing technologies, and this FlexTech grant to WMU’s Center for the Advancement of Printed Electronics will help bring additional cutting edge research to our state,” said Senator Carl Levin (D-MI). “This is a fine example of how Michigan’s higher education institutions are contributing to the nation’s research and development needs.”

The FlexTech Alliance program is a collaborative effort of private industry and the U.S. Army Research Laboratory, located in Adelphi, MD. It is devoted to fostering the growth, profitability and success of the electronic display and the flexible, printed electronics supply chain. For more information, visit www.flextech.org.

Center for the Advancement of Printed Electronics (CAPE) was formed to meet the multidisciplinary challenges of printed electronics. A team of 13 researchers from the Departments of Paper Engineering, Chemical Engineering and Imaging, Electrical and Computer Engineering, Manufacturing Engineering, Mechanical Engineering, Chemistry and Physics, Western Michigan University are currently working together on research funded through federal and state agencies, industry partners and a recently formed an Electronic Device Consortium. CAPE focuses on printing as a low cost means for manufacturing electronic devices. The emphasis is on technologies that can be used on a printing press, thus taking full advantage of the benefits printing can bring to electronics manufacture.

Read more about printed electronics:

Printed, flexible integrated circuits in real-world applications

Xerox: Silver ink pushes plastic electronics forward

X-Fab adds Semprius’ chip printing to foundry lineup

(July 7, 2010) — Biotage (STO: BIOT), tools and technology supplier for analytical and medicinal chemistry, debuted the high-performance AFFINILUTE molecularly imprinted polymers (MIP) columns for analytical sample preparation. Highly selective extractions with AFFINILUTE MIPs are simplified, targeting faster, more robust, and lower cost sample preparation.

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AFFINILTE MIP columns contain engineered cross-linked polymers that exhibit high affinity and selectivity towards a single compound or class of compounds. They suit extraction of analytes from complex matrices such as plasma, urine, muscle tissue, food matrices, and environmental samples. The selectivity of AFFINILUTE MIPs allows for trace level extraction (<ppb) of target analytes in the presence of large excess of other compounds with similar physico-chemical properties.

Biotage AFFINILUTE MIP columns offer analytical chemists ultimate selectivity compared with standard solid phase extraction techniques.  Unlike other methods, they rely on the specific molecular structure of the analyte for targeted capture resulting in exceptional clean up. AFFINILUTE combines high affinity with standard flow through sample preparation methodology.

The highly selective AFFINILUTE MIP columns serve a wide variety of analytical chemists in environmental, forensic, clinical and food testing laboratories. Typical analytes include Beta-blockers and Beta-agonists, Riboflavin (vitamin B2), triazine herbicides, antibiotics, tobacco specific by-products, amphetamines, fluoroquinolones, nitroimidazoles and more.

Biotage sample preparation products are supported the company for method development, choosing the right product and most efficient method that best suits analytical needs, says Scott Carr, VP of commercial operations.

Biotage offers products, knowledge, and experience in the areas of analytical and medicinal chemistry. The customers include the world’s top pharma and biotech companies, as well as leading academic institutes. For more information, visit www.biotage.com

Read more about nanotechnology in the bio/medical sciences.

(July 7, 2010) — AMT — The Association For Manufacturing Technology will join forces with the National Association of Manufacturers (NAM) to promote the importance of manufacturing and innovation in the U.S. economy. This partnership will bring the organizations together in support of the IMTS 2010 International Manufacturing Technology Show, sponsored by AMT and held at Chicago’s McCormick Place, September 13-18, 2010. 

“Collectively, our members represent every stage of the production process — from the mind of the design engineer to the shop and factory floor to the global marketplace. Together, we want to underscore the importance of a strong manufacturing sector to long-term economic growth and national security,” said Douglas K. Woods, President of AMT. 

NAM president and CEO John Engler will give a keynote address in the Emerging Technology Center on day two of IMTS, September 14, 2010. Engler will highlight how investment in innovation, technology, and technical skills are critical to a strong U.S. manufacturing sector. The former Governor of Michigan will also provide insights on how the federal U.S. and individual states can create an economic climate that encourages innovation.

“We are pleased to partner with AMT on IMTS 2010, where companies will see the latest breakthroughs in manufacturing technology. Innovation along with research and development has long helped manufacturing in the United States maintain its global leadership,” said Engler.  “But while we continue to stand strong as the number one manufacturing economy in the world, we face strong competition from other countries.”

NAM recently released “A Manufacturing Strategy for Jobs and a More Competitive America,” which details what policies lawmakers can adopt and advocate to keep manufacturing successful and competitive in a growing global marketplace. AMT has a Manufacturing Mandate calling for a federal policy of collaboration between government, industry, and academia to place incentives on innovation and R&D in new products and manufacturing technologies; assure the availability of capital; increase global competitiveness; minimize structural cost burdens; and enhance and build a better educated and trained smartforce, make a strong statement calling for action to support manufacturing.

For more information on the keynote and tradeshow, visit www.IMTS.com.

AMT supports and promotes the U.S. manufacturing technology industry.  The association provides U.S. builders of manufacturing systems with the latest information on technical developments, trade and marketing opportunities, and economic issues.  It also gathers and disseminates information about world markets, promotes its members’ products in those markets, and acts as a representative on manufacturing technology matters to governments and trade organizations throughout the world.

The National Association of Manufacturers represents manufacturers in every industrial sector and in all 50 states.  For more information, visit www.nam.org

(July 6, 2010) — Surrey NanoSystems launched an automated, versatile growth platform, NanoGrowth-Catalyst. Incorporating nine advanced nanomaterial processing techniques, the platform can synthesize a variety of nanomaterials including graphene, nanowires, and carbon nanotubes.

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Application versatility is enhanced by a multi-chamber design that ensures the purest processing conditions by continuously maintaining the substrate under vacuum from deposition of catalysts to growth of nanomaterials. This end-to-end vacuum processing is critical for the precursors and catalysts used for nanomaterials, which are easily contaminated by exposure to atmosphere.

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Surrey NanoSystems previously introduced a platform combining CVD and plasma-enhanced CVD nanomaterial growth techniques, says Ben Jensen of Surrey NanoSystems. "This new platform takes processing flexibility much farther. It offers the means to support and speed research across the spectrum of nanomaterials, combined with automated handling and control to help developers turn material growth ideas into practical and repeatable production processes."

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NanoGrowth-Catalyst will replace multiple pieces of equipment with a single automated system. The processing techniques supported by the new platform are low-pressure chemical vapor deposition (LPCVD) and plasma-enhanced CVD (PECVD), sputtering, sputter etching and ashing, delivery of solid- or liquid-phase catalysts/precursors, creation of controlled-density nanoparticle catalysts at room temperature, thermal annealing, rapid thermal processing (RTP), and a unique form of rapid thermal growth (RTG) that prevents agglomeration of catalyst particles.

The platform also supports broadband substrate degassing to remove surface contaminants before processing, helping to ensure the optimum adhesion of catalysts and films. An inductively coupled plasma source can additionally be fitted as an option at purchase or during the platform’s lifecycle, to optimize the generation of sensitive materials employed in growth processes.

A graphical user interface (GUI) controls the processing parameters and steps. With its range of techniques users can employ NanoGrowth-Catalyst for creating or delivering growth catalysts and precursors (the sputtering platform’s dual magnetrons also support co-deposition), depositing nanoparticles at room temperature, catalyst or material activation, growing materials, etching, and deposition of active or passive barrier films.

The system has three chambers: a load/lock chamber and two reaction chambers, plus an automatic transport system for moving wafers/substrates. End-to-end atmosphere-free processing ensures the highest purity conditions to minimize contamination and oxidation and ensure consistent and repeatable results. NanoGrowth-Catalyst occupies a cleanroom footprint of 1 × 2 m.

The specification for this platform came partly from requests by users of Surrey NanoSystems’ single reaction chamber NanoGrowth 1000n, and from researchers at Surrey NanoSystems and its research partner, the Advanced Technology Institute at the University of Surrey.

Surrey NanoSystems has received advance orders for the new NanoGrowth-Catalyst, and is currently manufacturing an initial batch of three systems.

In addition to making growth platforms, Surrey NanoSystems is engaged in developing nanoelectronics materials and processes to support the continued scaling of semiconductor devices. The company has already made significant advances in developing practical techniques for fabricating interconnection vias and low-k dielectrics for inter-layer insulation. For more information, visit http://www.surreynanosystems.com. Surrey NanoSystems is represented in the USA by Axiom Resources Technologies, www.axrtech.com

(July 1, 2010) — A new German nanotechnology company has started its business: Particular GmbH has commercialized a novel process for the production of highly pure nanoparticles.

The developments were made at Laser Zentrum Hannover e. V. (LZH) and took five years. Niko Bärsch, CEO of Particular, explains that their nanoparticles make it easier to take advantage of nanotechnology for many products, especially in the field of medical technology.

Nanoparticles are invisibly small material pieces that improve products’ biological compatibility, bacteria resistance, UV light absorption, or scratch resistance. While they are usually generated chemically, the new company produces them physically by laser ablation in liquids. This enables new kinds of nanoparticles, for example for metallic surfaces with securely attached nanostructures that make implants more compatible, or for a conjugation of smallest gold particles and biomolecules for biomedical applications such as cell separations.

For more information, visit http://particular.eu

(July 1, 2010) — Ariadne announces a new collaboration with the BIO-NMD consortium led by Professor Alessandra Ferlini at the University of Ferrara, Italy. BIO-NMD is a three year, 7.5M€ EU-funded medical research project concentrating on the search for non-invasive biomarkers in people with Duchenne and Becker muscular dystrophies and Collagen VI myopathies. The consortium, along with leading European academic research and industry partners will work to identify non-invasive biomarkers for monitoring neuromuscular diseases (NMDs). Utilizing a myriad of OMIC sciences (genomic, transcriptomic, proteomic) and bioinformatics, the consortium hopes to bring qualified biomarkers for ongoing and further clinical trials.

Ariadne’s focus will be on providing bioinformatics tools for identifying functional pathways, potential targets and data outflow integration. The team will use its software, Pathway Studio®, as a core to integrate the data and information flow, in addition to using its expertise in information extraction to develop a literature-derived NMD biological knowledgebase of related processes and diseases. Specifically, Ariadne will build mechanistic models and pathways for NMD and interpret OMIC data generated by the consortium and partners in the context of NMD knowledgebase and networks.

BIO-NMD’s coordinator and chair of the steering committee, Professor Alessandra Ferlini (University of Ferrara, Italy) said, “The participation of Ariadne as partners together with INSERM is crucial for the project. Developing bioinformatic tools for OMIC studies analysis is essential and guarantees success to the project. In addition, it reinforces collaboration between academics and industries, again a key point for successful research to be translated into clinics.”

“We have always worked to establish strong collaborations with our clients”, says Gabriella Armin, Director of Marketing for Ariadne. “Given the importance of this project, we are proud to not only provide the technology to enable this type of innovative discovery research, but contribute scientifically as team members. Our technological expertise in knowledge enrichment continues to provide crucial bioinformatics tools for visualizing the complexity found in biology.”

The first update workshops for the BIO-NMD consortium are to be held in July in London and will include sessions dedicated to its industrial partners. The consortium will present and describe the project impacts, possible outcomes and identify links for future collaborations with industry. For further details about the project please visit the BIO-NMD website at www.bio-nmd.eu

Ariadne (www.ariadnegenomics.com), a leader in research data products and knowledge enrichment-based software solutions, helps pharmaceutical and life science researchers tap known scientific knowledge for applications in systems biology and translational medicine. Products include custom data products, knowledge extraction and visualization software, knowledge reports, and informatics staffing.

BIO-NMD (www.bio-nmd.eu) is an EU-funded project devoted to the discovery and validation of biomarkers in muscle dystrophies with the aim of improving disease and therapy monitoring. It is a translational project which will focus on Duchenne and collagen VI myopathies. The project is a consortium of 12 partner institutions led by the University of Ferrara’s Prof. Alessandra Ferlini, funded until Dec 2012.

Read more about Nanotechnology in Medical Sciences

Read more about University Research

(July 1, 2010) — Inspired by the ease with which gecko lizards can move on almost any surface, researchers at Northeastern University, the Korea Institute of Science and Technology and Seoul National University hope to reproduce properties found in the gecko’s footpad for applications ranging from adhesives to robotic movement and navigation.

The team, led by Ashkan Vaziri, assistant professor of mechanical and industrial engineering at Northeastern; and Myoung-Woon Moon, of the Korea Institute of Science and Technology, created nanoscale and microscale patterned surfaces with adhesion and friction properties similar to that of the gecko footpad.

Asymmetric adhesion is used by many insects and gecko lizards, allowing them to move on nearly any surface – horizontal, tilted or vertical. Many of these creatures have feet covered by intricate fibrillar structures that are responsible for their superb climbing ability. Among these creatures, gecko lizards have one of the most efficient and interesting adhesion devices consisting of finely angled arrays of branched fibres (setae). Gecko toes are covered by millions of hair-like setae, each of which is five micrometers in size — smaller than a human hair. The ends of the setae are tipped with hundreds of spatula, which bend and conform to the surface on which the gecko is moving.

The innovative nanotech methodology, published online and in the academic journal Soft Matter, could lead to the development of a “smart” adhesive that adapts to environmental stimuli, such as a curvy surface or a rough edge.

“The gecko footpad’s unique structure and function make it one of the most efficient adhesion systems found in nature,” said Vaziri, who also directs Northeastern’s High Performance Materials and Structures Laboratory.

The research team designed and created a series of micropillars, or hair-like structures, and exposed them to ion beam radiation. The radiation tilted the micropillars, resulting in a dual-surface area with unique adhesion and friction properties. 

Through a series of experiments, the team found that the micropillars had qualitatively similar friction properties and function when compared to the gecko footpad.

“If equipped with micropillars, small high-tech robots (for research or military applications) might be able to climb with speed, precision and accuracy on uneven, slippery surfaces,” said Vaziri.

The technology also could lead to a new generation of smart adhesives that are equipped to hold strong bonds with any surface, he said. The polymer micropillars don’t yet have the hierarchical structure found on a gecko’s setae. This is something the team hope to replicate in the future.

Read the Journal article in Soft Matter here.

Read more University research announcements here.

July 1, 2010 – After a tough year in 2009, MEMS auto sensors will rebound sharply in 2010, though there’s a danger of overheating and braking the market back into a recession, says analyst firm iSuppli.

Global shipments will top 591M units this year, up nearly 18% from a year ago (502M units). Orders to sensor companies practically dried up during the overall economic meltdown — but by 4Q09 shipments picked up quickly, exceeding 2007’s record levels. Look for an upturn through at least 2014, the firm projects, in a new report.

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Leading the charge for the rejuvenated automotive MEMS market are pressure sensors, used for measuring tire pressure and engine performance, thanks in part to ramping production of passenger vehicles and inventory replenishment. Shipments are running at 3× the historic average, iSuppli says, citing "at least half" of suppliers. Through April, about half the year’s expected requirement for MEMS pressure sensors had been satisfied; some major Tier 2 suppliers are unable to keep up, and Tier 1s are indicating a shortage of some parts, the firm notes.

Vertically integrated suppliers Robert Bosch ($355M) and Denso ($203M) dominated the market in 2009, with others including Freescale ($139M), Sensata ($115M), Analog Devices ($95M), and Panasonic ($85M). The latter gained market shares with gyroscopes due to contracts with Continental AG and TRW (for ADI) and Ford (for Panasonic).

A mandate for growth

While MEMS suppliers are taking full advantage of their situation, there is increasing skepticism about the direction of the industry, iSuppli says. If sales stay at current levels — and they don’t show signs of slowing down — there could be overheating and possibly a second slump later in 2010.

What’s driving MEMS sensor adoption in cars, from an average of 8.12 per vehicle in 2009 to >11.5 in 2014? In a word — mandates. Electronic stability systems in vehicles will be mandatory in the US in 2012, and in the European Union by 2014, which also will require tire pressure monitoring system (TPMS). Look for these to boost sales of gyroscopes, accelerometers, and high-pressure sensors — and MEMS pressure sensor shipments will more than triple from 2009 to 2014, to 137.9M units.

Another growth area in auto MEMS is powertrain sensors, used in pressure and flow measurements in engine combustion control — also being increasingly driven by emission reduction regulations. Alongside established markets for managing manifold & barometric air pressure, emerging systems that turn the engine off/on at junctions will surge from about 1M units today to 13M units in 2014, iSuppli says.

China’s MEMS emergence

By region, North America makes up the largest share of MEMS consumption (40% in 2010), followed by Europe (about 33%), followed by China, and Japan and "Rest of World (including South Korea, Russia, and Latin America). But going forward, China is "the new motor of the automotive market,"iSuppli proclaims — it had 11% consumption of total MEMS shipments in 2009 and should surpass Japan and ROW by 2014. Even with lower electronics content than more mature markets, and without mandates today, about 10% of cars in China feature electronic stability control and two satellite airbags are common in many midrange autos (vs. 3-4 in the US and EU vehicles). In larger cities such as Beijing and Shanghai, powertrain sensors such as manifold absolute pressure sensors to feed information to internal combustion engines’ electronic control system.

With more car shipments headed to China, suppliers with a footprint in that region (e.g. Bosch, Continental) managed to avoid the worst of the recession. And local suppliers seeking to get into the game will likely stick with "less complicated" pressure sensors instead of inertial sensors (e.g. accelerometers and gyroscopes), "posing less of a threat to the existing MEMS supply chain," iSuppli says.

Click to EnlargePete Singer
Editor-in-Chief

Increasingly, we are hearing about consolidation in the semiconductor industry. Bill McClean of IC Insights has perhaps pointed this out most clearly, noting that the top 10 capacity leaders held about 60% of the total 2009 worldwide IC capacity, and the top 15% held a 71% share. Looking at only 300mm capacity, the consolidation is even more obvious: the top 10 leaders held an imposing 84% share with the top 15 companies holding all but 8% of the world’s 300mm IC fabrication capacity, according to McClean.

This is good news for those15 companies, but not such good news for consumers. "With so few companies representing such a large share of the leading-edge IC production, IC Insights’ long-held belief that the companies left standing after the ‘shakeout’ will reap the rewards of increased profitability, is now coming true. However, for the IC user, this also means that IC average selling prices are unlikely to decline as they have in the past. The pricing pendulum is now swinging in favor of the IC producers and it may not be swinging back for a long time," McClean said.

With a greater percentage of spending coming from a shrinking number of companies, semiconductor industry capital spending is becoming more concentrated. Because of this trend, IC industry capacity is also becoming more "concentrated." As tight as overall IC capacity has been in the IC industry since the first half of 2009, 300mm capacity has been even tighter, McClean notes. In 1Q10, 300mm capacity utilization was 97%, which is essentially indicate a "sold out" situation.

With most capital spending in 2010 going toward developing and moving to finer feature sizes (with little going toward adding wafer starts), the availability — or lack of availability — of IC devices will become a major factor in the second half of this year. Ion fact, IC Insights believes that one limiting factor to 30% or greater IC market growth in 2010 might be the lack of IC fabrication capacity needed to support such growth.

Also expect higher average selling prices (ASPs) for almost all types of ICs. "Given that almost all DRAM, NAND flash memory, and microprocessors are produced using 300mm wafers, it follows that each of these segments registered increasing average selling prices throughout 2009 and into 2010," McClean said. "IC Insights believes that buyers of these IC devices should be prepared for similar ASP trends for these products in the second half of this year."

While all of this is going on – the consolidation, sold-out capacity and higher selling prices for mainstream ICs – I keep thinking applications that fall outside of the mainstream. Where are those apps that require different types of equipment and materials technology and different process technology? Do they exist? How big of a market do they represent? Might they be a way for suppliers to diversify outside of the mainstream 15-companies-now-controlling-all-the-spending semiconductor industry?

My list of applications that offer a potential way to diversify for companies offering thin film deposition and patterning capabilities include: MEMS, hard disks and read-write heads, flat panel displays, optical disks, photovoltaics, LEDs, CMOS image sensors, and superconductors. The MEMS market is perhaps the most intriguing of these since it encompasses so many different types of devices, from microphones to sensors to micro-fluidic labs on a chip.

But perhaps the application with most explosive potential is intelligent medicine. Imagine taking a digestable "smart" pill that is in essence an integrated circuit. As that pill works it’s way through your body, it monitors the status of all kinds of functions and reports the results to your iphone or similar device. That kind of technology is, in fact, already here. Proteus BioBed in Redwood City, CA has developed what it call the Raisin™ System (there was an Apple on your desk, a Blackberry on your belt and now a raisin inside, quips Proteus CEO Andrew Thompson). The initial application of the Raisin System is for the treatment of patients with heart failure. The system senses and records the precise time a patient takes one or more microchip-enabled drugs, providing physiologic feedback and decision-support to the patient, caregivers and clinicians, thus facilitating a cost-effective pathway to improved patient outcomes through personalized medicine.

How cool is that!? It doesn’t take much imagination to envision all kinds of medical apps with new and unique requirements that could leverage traditional IC manufacturing technology. This market could be huge, given the aging baby boomer population and over-loaded healthcare system. Consolidation? Who cares? Bring on the new apps!

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