Tag Archives: Small Times Magazine

August 29, 2011 — The University of Rochester, joined by US Representative Louise Slaughter (NY-28), opened the Integrated Nanosystems Center (URnano) on campus. The center will be used for nanoscale physics, optics, chemistry, biomedicine and bioengineering research on commercialization of fuel cells, biosensors and other high-tech devices.

URnano comprises a 1000sq.ft. metrology facility and a 2000sq.ft. cleanroom for fabrication.

Congresswoman Louise Slaughter helped bring the "impressive, state-of-the-art facility" to the Rochester campus, said University President Joel Seligman. Congresswoman Slaughter secured a total of $4.4 million in federal money across three funding cycles to make the project possible. The work started in 2007, Congresswoman Slaughter recalled, who championed the lab for its job- and company-creation potential. It will "train the next generation of scientists and engineers in nanotechnology," she added.

The center will enhance University of Rochester’s existing engineering strengths, and encourage collaboration with industry, Seligman added. It complements other nanotech research in New York State, including UAlbany’s College of Nanoscale Science and Engineering (CNSE) and facilities at Cornell and Rensselaer Polytechnic Institute, pointed out Nicholas Bigelow, the Lee A. DuBridge Professor of Physics, department chair, and Director of URnano. The University of Rochester is able to produce high-temperature nanomaterials and integrate optical device research and development.

URnano is part of the Hajim School of Engineering and Applied Sciences. The University of Rochester is a leading private university. Learn more at www.rochester.edu.

August 26, 2011 — Attend the Nanomanufacturing Summit 2011 keynote address, Tuesday, September 27, 10:00-10:30AM, to hear Dave Arthur, CEO of SouthWest NanoTechnologies Inc. (SWeNT), discuss carbon nanotube (CNT) commercialization, as well as the roles of nano inks and coatings in broad applications.

The Nanomanufacturing Summit 2011 & 10th Annual NanoBusiness Conference are held September 25-27 in Boston at the Seaport Convention Center. To attend, visit http://www.internano.org/nms2011/

SWeNT produces conductive and semiconducting CNT inks based on V2V technology. They can be deposited using commercial, high-volume printing methods and equipment. Additive printing eliminates the waste and additional process steps of subtractive patterning, Arthur explains. He adds that the printed nano coatings no dispersants or viscosity modifiers that could degrade performance.

SWeNT also tailors CNT materials for different applications via its CoMoCAT process. Applications include energy-efficient lighting, affordable photovoltaics, improved energy storage, and printed electronics. The Summit and co-located conference highlight nanotechnology and nanoscience applications that are commercially viable in the near term.

SouthWest NanoTechnologies Inc. (SWeNT) is a specialty chemical company that manufactures high quality single-wall and Specialty Multi-Wall (SMW) carbon nanotubes, printable inks and CNT-coated fabrics. SWeNT was created in 2001 to spin off nanotube research developed at the University of Oklahoma. For more information, visit www.swentnano.com

August 26, 2011 — The MEMS Industry Group (MIG) welcomed Frauhofer Institute for Silicon Technology (ISIT) to its membership. The research facility focuses on microelectronics and microsystems technology. Siconnex, which builds diverse MEMS fab equipment, also joined the association.

Fraunhofer ISIT operates a 3,000m2 cleanroom for microsystems research and production, sporting Rudolph and SPTS equipment, among others. The staff includes 150 scientists, along with industry partners. They develop power electronics, sensors and microsystems based on micro electro mechanical systems (MEMS), as well as actuators using micro mirrors, valves, etc. Visit Fraunhofer ISIT’s website at http://www.isit.fraunhofer.de/en/ (English language version). The facility joins Fraunhofer IPMS and Fraunhofer ENAS, existing MIG members.

Siconnex Customized Solutions, based in Austria, supplies MEMS manufacturers with coating and deposition systems, metal lift off (MLO) tools, and wet batch sprayers for etch and clean operations. Learn more at http://www.siconnex.com/

MEMS Industry Group offers programs and events to advance MEMS commercialization and manufacturing in global markets. Members include MEMS makers such as Knowles, equipment suppliers such as Applied Materials, and research organizations such as imec. Learn more at www.memsindustrygroup.com.

Recent Fraunhofer MEMS research:

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August 25, 2011 — Cintelliq’s "OLED lighting: A review of the patent landscape" report shows the fastest growth in organic light emitting diode (OLED) patents 2008-2010 came from the materials sector. During the 2-year period, the total number of OLED patents published grew by 56% from 1,767 to 2,760, with no signs of slowing. The largest group of OLED patents (>260) went to traditional lighting companies.

Patent filings by academic and research institutes grew by nearly 200%. During the same period, device patents growth was the highest in terms of absolute numbers, but the highest growth rate was in terms of patents for ‘ancillary’ aspects of OLED panels: drimmer units, power units, mountings and fixtures. Applications patents, materials, fabrication and outcoupling all grew by more than 50%.

Figure. OLED patents by type, through 2010

Increasingly, patents refer to LED and OLED as the solid-state light source, suggesting that — from an applications persepctive — the two technologies are interchagable.

Table. Numbers of Industry Sector  Patents Assignees
Lighting 640 33
Imaging/optics 498 9
Technology providers 414 14
Display 331 38
Materials 289 40
Academia 159 51
Automotive 129 19
Other 300 92
Total 2,760 296

"OLED lighting: A review of the patent landscape" identifies more than 2,760 patents focused on white OLED technology for lighting applications, notes Craig Cruickshank, lead analyst, cintelliq Limited. Cruickshank expects OLED patent filings to continue to increase as "companies seek to secure exclusive technology domains." The research for this report is based on more than 2,700 patents – 310 granted patents (EP and US) and 2,450 published (EP, JP, US and WO), that have been made public up to December 2010.

Contact [email protected] to purchase the report.

Companies mentioned in the report:
3M, Acuity Brands, Airbus Operations, Applied Films, BASF, Beijing Visionox, Boeing, Cambridge Display Technology, CEAG Notlichtsysteme, Changchun Institute, CEA, Corning, CSIR, Dai Nippon Printing, Dongbu Hitek, Dongwoo Fine Chemicals, Doosan, DuPont, Eastman Kodak, FED, Foshan Nationstar Optoelectornics, Fraunhofer, Fuji Photo Film, Fujitec Intl., Furukawa Electric, General Electric, Global Energy Group, Global OLED Technology, Group IV Semiconductor, Harison Toshiba Lighting, Hitachi Chemical, Hitachi Lighting, Hitachi,  Idemitsu Kosan, ITRI, Jiaotong University, Johnson Controls Interiors, Kaneka, Katholieke Universiteit Leuven, Koizumi Lighting Technology, Konica Minolta, KETRI, LG Chemical, LG Display, LG Electronics, LG Philips LCD, Lighting Science Group, Lightronik Technology, Matsushita Electric Works, Merck, Mitsubishi Chemical, National Tsing Hua University Taiwan, NEC Lighting, Nitto Denko, Nokia, Novaled, Nth Degree Technologies, Osram, Panasonic Electric Works, Philips Electronics, Pioneer, Plextronics, Princeton University, Qinghua University, RIKEN, Rohm,  Saint Gobain Glass France, Samsung Electronics, Samsung Mobile Display, Samsung SDI, Sanyo Electric, Schott, Seiko Epson, Semiconductor Energy Lab, SFC, Sharp, Solvay, Sony, Stanley Electric, Sumitomo Chemical, TDK, Technische Universitaet Dresden, University of California, University of Michigan, University of St Andrews , Tohoku Pioneer, Toppan Printing, Toshiba, Toshiba Lighting, Toshiba Materials, Toshiba Matsushita Display Technology, Toyo Ink Manufacturing, Toyota Industries, Tridonic Atco, Universal Display, Vitex Systems, Yamagata Univeristy, Zeolux Corp, Zeon Corp.

August 25, 2011 – PRWEB — Magnetic sensors will exceed $3.2 billion in sales by 2017 driven largely by "E-compassing" applications, according to Global Industry Analysts (GIA). Unique end-use applications, along with technology innovations, interoperability with devices and competitive pricing, will fuel "robust" magnetic sensors growth, says GIA.

Better sensitivity, compactness and flexibility in today’s magnetic sensors has led to integration in high-end industrial/automotive applications through low-cost consumer and mobile products. Position sensors, speed sensors and record heads in hard disk drives in computers are the most commonly used magnetic sensor types. Smartphone and automotive-integrated magnetic sensors are enabling a host of new navigation functions in mobile and other GPS devices. Ultra-sensitive superconducting quantum interface devices (SQUIDs) are highly effective in medical applications for detection functions.

Thanks to the miniaturization of micro electro mechanical systems (MEMS), built using semiconductor fab processes, silicon-based magnetoresistive sensors (AMR, GMR) are enabling devices with functionality that hall devices cannot provide, and these sensors are replacing micro switches, potentiometers and reed switches. Manufacturers are investing in GMR technology development, attributed mainly to the significant growth in the HDD area density. Silicon magnetic sensors will flourish in mobile devices, desktop PCs; smartphones; gaming; audio and video devices and personal electronics.

The global 2008-2009 recession kept magnetic sensors growth flat, due to soft demand for all major end-use segments. Demand surged in 2010, mainly from the automotive, consumer and industrial markets, GIA notes. Also read: Digital compass manufacturing: With nearly all makers in Japan, will the earthquake affect supply?

The US and Europe represent equal contenders in the magnetic sensors market. Developing markets in Asia-Pacific and Latin America will add potential for companies with the right technology and product developments. Asia-Pacific, led by India, China, Korea and Taiwan, will see the fastest compound annual growth rate: 12% CAGR through 2017.

By product segment, Hall Sensor ICs constitutes the largest market globally. With respect to long-term potential, giant magnetoresistive (GMR) sensors are poised to take the lead, expanding at a CAGR of over 12%.

Companies mentioned in the report: Allegro MicroSystems, Inc, Asahi Kasei Microdevices Corporation, Austriamicrosystems AG, Honeywell International, Inc, Infineon Technologies AG, Melexis Microelectronic Systems, MEMSIC, Inc, Micronas Semiconductor Holding AG, NVE Corporation, NXP Semiconductors N.V., and Sensitec GMBH.

The research report "Magnetic Sensors: A Global Strategic Business Report" from Global Industry Analysts Inc. provides a comprehensive review of industry and product overview, market trends and issues, technology overview, end-use analysis, technological developments, product introductions, recent industry activity and profiles of market players worldwide. Analysis and overview is provided for major geographic markets such as US, Canada, Japan, Europe, Asia-Pacific, Latin America and Rest of World. Market analytics are provided in value (US$) terms for product segments including, Hall Sensor IC’s, Anisotropic Magnetoresistive (AMR) Sensors, Hall Sensor Elements, Giant Magnetoresistive (GMR) Sensors and Others. Major end-use sectors include Aerospace & Defense, Automotive, Industrial, Electronics and Others. The study also provides historic data for an insight into market evolution over the period 2003 through 2008. Learn more at http://www.strategyr.com/Magnetic_Sensors_Market_Report.asp

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August 25, 2011 — A new nanoscale parameter discovered by Aalto University shows that silicon nanoparticles can be compressed to half their size without breaking. This deviation from bulk material properties (wherein silicon is brittle) could lead to new nanoscale device designs from on-chip lasers to drug delivery vehicles.

Researchers squeezed silicon spheres and tracked the resultant atomic rearrangements. Material response varied depending on the degree of deconfinement that contrasts the "size effect." Smaller material volumes displayed unexpected deformation mechanisms under mechanically induced shape changes.

Also read: Graphene is not: Metal, semiconductor, or insulator

Bulk silicon displays plasticity characterized by phase transformations. However, less-constrained silicon nanoparticles deviate from this mechanical response, compressing to half their size without breaking. Researchers call this the "nanoscale confinement" parameter. They expect the phenomenon to resolve issues discovered in other studies, where silicon behaves differently at different sizes.

The study provides a basis for understanding the onset of incipient plasticity in nanovolumes. This is a repeatable process that could generate crystal structures to enhance Si’s functional properties and biocompatibility.

Professor Roman Nowak, Nordic Hysitron Laboratory, Aalto University led the research, in cooperation with the Department of Chemical Engineering and Materials Science, University of Minnesota, Minneapolis, while the calculations were consulted with Professor Risto Nieminen of CSC-IT / Aalto University.

The discovery is recently published in Nature Nanotechnology: D. Chrobak, N. Tymiak, A. Beaber, O Ugurlu, W.W. Gerberich and R. Nowak, Deconfinement leads to changes in the nanoscale plasticity of silicon, Nature Nanotechnology 6 (2011) 480-484. Access it here: http://www.nature.com/nnano/journal/v6/n8/abs/nnano.2011.118.html

The research was supported by the Academy of Finland, CSC-IT Center for Science (Finland), the Foundation of Helsinki University of Technology, Ceramic Society of Japan and National Science Foundation (USA).

Learn more at http://www.aalto.fi/en/ (English language version)

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August 24, 2011 — Pico projectors, small projector modules that can be integrated into cell phones, mobile gaming devices, and other electronics, are just gaining market adoption. However, expect pico projectors to exceed 97.5 million units, with revenues hitting $10 billion, by 2017, says Global Industry Analysts Inc. (GIA).

Pico projectors were a 10-model, several-thousand-unit market in 2008. Advances in miniaturization and quality, along with dropping prices, will spur a host of new models in the next 5 years, most designed for embedding in mobile electronics.

The projectors easily fit in with smartphones, digital cameras, and other devices, offering video play, photo and document sharing, video game play, and other functionalities on any surface. Mobile handsets are expected to stimulate the highest growth in pico projectors market. Apple is rumored to be making a line of pico projectors. Cellular service providers could subsidize pico-projector-enhanced phones, benefiting from increased content fees by users.

Beyond mobile consumer devices, pico projectors are finding a market in schools and other educational institutes, thanks to better costs and storage requirements than traditional projectors.

Pico projectors historically used liquid crystal on silicon (LCOS) microdisplays with color filters (2008-2009). LCOS with color sequential, digital light processing (DLP), and laser beam steering (LBS) or scanning micro electro mechanical systems (MEMS) are coming into use today. In the future, DLP will fuel the majority of pico projectors, followed by LCOS. MEMS scanning technology will see the fastest adoption rate.

Lasers and LEDs are the two predominantly used light sources, with lasers eventually overtaking LEDs, after the commercial introduction of direct green laser. Lasers best suit pico projectors owing to saturated colors projected across the broadest color spectrum, as well as power efficiency, higher resolution, and focus-free operation.

Pico projectors are largely produced in the US, where many of the market pioneers operate. As new players rapidly infiltrate the market, producers could specialize into "accessory" and "standalone" pico projector categories. Major players in the accessory segment include 3M Company, AAXA Technologies Inc., Acer Incorporated, Aiptek Inc., Optoma Corporation, Samsung Electronics Co., Ltd., Toshiba Corporation and WowWee Group Limited. Leading module/chipset manufacturers include bTendo Ltd., Lemoptix SA, Light Blue Optics, Luminus Devices Inc., Maradin Ltd., Mezmeriz Inc., Micron Technology Inc., MicroVision Inc., Opus Microsystems Corp., Syndiant Inc., and Texas Instruments Inc.

Global Industry Analysts Inc. published "Pico Projectors: A Global Strategic Business Report" covering these market trends, issues, drivers, company profiles, mergers, acquisitions, product launches and other strategic industry activities. The report provides market estimates and projections in volume (in thousand units) as well as value terms (US$ Million) for the US, Canada, Japan, Europe, Asia-Pacific, Latin America, and Rest of World markets.

For more details about this comprehensive market research report, visit http://www.strategyr.com/Pico_Projectors_Market_Report.asp

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August 24, 2011 — Research by an interdisciplinary — pathologists, engineers and chemists — team of scientists at Brown University found that nickel nanoparticles activate a cellular pathway that contributes to cancer in human lung cells.

Nanoparticles offer unique properties for research and industry, but must be designed to avoid health risks, and hazards must be identified, said Agnes Kane, chair of the Department of Pathology and Laboratory Medicine in The Warren Alpert Medical School of Brown University.

Nickel nanoparticles have ions on the surface that are released inside human epithelial lung cells to jumpstart a pathway called HIF-1 alpha. This pathway normally helps trigger genes that support a cell in times of low oxygen supply, or hypoxia, but it is also known to encourage tumor cell growth.

Nickel nanoparticles "trick" the cell into reacting to nonexistent hypoxia, said Kane, who says nickel "exploits" this pathway. The pathway could give premalignant tumor cells a head start.

Figure. When human lung epithelial cells are exposed to equivalent doses of nano-sized (left) or micro-sized (right) metallic nickel particles, activated HIF-1 alpha pathways (stained green) appear mostly with the nanoparticles.

The research team, led by postdoctoral research associate Jodie Pietruska, exposed human lung cells to nanoscale particles of metallic nickel and nickel oxide, and larger microscale particles of metallic nickel. While the nanoparticles set off the HIF-1 alpha pathway, the larger metallic nickel particles did not cause the same reaction. For the same amount of metal by mass, nanoscale particles expose much more surface area, which could cause their increased chemical reactivity.

The nickel nanoparticles and nickel oxide nanoparticles react with cells differently, Pietruska said. Nickel oxide particles kill cells exposed to them quickly, which prevents any cancer-cell development. Metallic nickel particles were less likely to kill the cells, leaving the hypoxia pathway active, and possibly leading to the cell becoming cancerous. "Metallic nickel nanoparticles caused sustained activation but they were less cytotoxic," summarized Pietruska said.

The findings lead Kane to recommend nickel nanoparticle handling precautions, such as preventing airborne exposure in manufacturing. The Brown lab handled the materials under biosafety level 2 containment conditions.

While the nanoparticles were linked to cancer pathways, other biological changes would also need to happen for cancer to develop. Further research is needed on long-term exposure, and beyond the cell level.

Results were published in advance online this month in the journal Toxicological Sciences. Access it online here: http://toxsci.oxfordjournals.org/content/early/2011/08/09/toxsci.kfr206.abstract?sid=14955fe9-77a1-494f-8abc-e7e7edbc6ee7

The work is supported by a National Institues of Health Superfund Research Program Grant.

In addition to Kane and Pietruska, other authors on the paper are Xinyuan Liu, chemist; Ashley Smith, doctoral student in pathobiology; Kevin McNeil, pathology lab technician; Paula Weston, histotechnician; Anatoly Zhitkovich, toxicologist; and Robert Hurt, engineer. Kane, Hurt, and Zhitkovich are associated with Brown’s Institute for Molecular and Nanoscale Innovation.

Learn more at http://brown.edu/

Nanoparticles have also been shown to fight cancer at Brown.

August 23, 2011 — The Center of Innovation for Nanobiotechnology (COIN), a non-profit commercialization center dedicated to the development and growth of nanobiotechnology-related industries, appointed Griffith Kundahl its executive director.

Kundahl will attend the Commercialization of Micro-Nano Systems (COMS) event, August 28-31 in Greensboro, NC, which COIN co-hosts with the Micro and Nanotechnology Commercialization Education Foundation.

Commercialization of nanobiotechnologies, locally, nationally and internationally will be Kundahl’s main charter, explained Roger Cubicciotti, Chairman of the COIN Board of Directors and President of Nanomedica Inc. COIN "strategically aligns across the value chain with the investment community, universities, researchers, and government labs and regulatory agencies," added Rob Burns, SVP of Lux Research.

Kundahl has an extensive background in emerging technology law, public policy, communications, and industry relations. He formerly served as General Counsel of the NanoBusiness Alliance, the national trade association for the nanotechnology community, as well as Executive Chairman of the Colorado Nanotechnology Alliance. He was also the Vice President for Convergence (nano, bio and IT) in the Life Sciences section of Ogilvy Public Relations Worldwide. Most recently, Kundahl served at the University of Denver School of Engineering and Computer Science as Director of Global Programs. Kundahl holds a bachelor’s degree from The University of Pennsylvania, a master’s degree from The University of Alabama and a law degree from The University of Denver.

COIN is a non-profit, virtual center of innovation serving as a catalyst for commercialization in the healthcare, agriculture, water, and energy sectors. Visit COIN’s website at www.nanobiotech.org.

August 23, 2011 — The automotive micro electro mechanical system (MEMS) sensor market will rise in 2012, steadying after 2010-2011’s cycles of growth and contraction, according to IHS iSuppli’s Automotive MEMS Market Tracker. Revenues will increase 16% to $2.31 billion, initiating a growth cycle that will hit $2.93 billion in 2015 (9% 5-yr CAGR).

MEMS sensors are integrated into safety, performance, and comfort features of automobiles: air bags, tire-pressure monitoring systems (TPMS), vehicle stabilization control, etc. As vehicle production recovers from the recession, and safety regulations become more encompassing, auto MEMS will experience healthy growth, said Richard Dixon, senior analyst for MEMS and sensors at IHS.

The Japanese earthquake in March 2011 significantly disrupted this year’s sales, both of MEMS and automobiles (2 million vehicles lost). Global automotive MEMS revenue in 2011 will reach $1.99 billion, up 4% from $1.91 billion in 2010. Shipments will be average: rising 9% to 750.7 million units, compared to a 36% increase 2009-2010. "The loss in vehicle production could entail a shortfall in sensor shipments equivalent to some 20 million units this year," Dixon posits.

As vehicle production comes back on-line, and automotive safety mandates on electronic stability control systems (ESC) go into effect (United States, Canada, Australia, Europe and Japan), multiple MEMS sensors will be integrated into each vehicle.

China’s "aggressive" fitment rates must be attained by 2015, which will dramatically increase pressure sensor sales for direct TPMS. The mandate will begin phasing in starting in mid-2012, beginning with a portion of engine sizes larger than 1.6 liters. In July 2015, the mandate will apply to all engine sizes, IHS iSuppli research shows.

Globally, TPMS sensor shipments will grow fivefold, propelling the market to 73% penetration of all vehicles by 2015. Tough price cuts of up to 8% per year will test the pressure sensor makers’ business viability.

Learn more in 2012 Sees Automotive Sensor Market Back to Healthy Growth Pattern at http://www.isuppli.com/MEMS-and-Sensors/Pages/2012-Sees-Automotive-Sensor-Market-Back-to-Healthy-Growth-Pattern.aspx?PRX

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