Category Archives: MEMS

March 7, 2012 – BUSINESS WIRE — MEMSCAP (Paris:MEMS), provider of micro electro mechanical system (MEMS) based products, topped 1 million units shipped of its Thermally Actuated Variable Optical Attenuator chips.

MEMS-based variable optical attenuators are integrated in complex optical modules operating up to 100 GBits. They suit optical networks applications ranging from optical modules protection to power management. The optical networking chips enable faster Internet connections and multiservice solutions.

MEMSCAP has supplied multiple customers from the beginning of its innovative photonic road map up to full product release. The company focuses on high-quality MEMS devices, and in February 2011 confirmed that MEMS VOAs operate within spec after 200 million cycles (from die-level testing).

MEMSCAP supplies thermally actuated VOAs in normally open and normally closed configurations (MATT VOA), including different die sizes, shapes and attenuation specifications to address customer demands. In 2011, MEMSCAP released multiple Variable Optical Attenuator dies using electrostatic actuation (ES VOA), operating under high or low voltage. Its VOA die fit most packaging technologies and in closed-loop mode exhibit strong optical power attenuation stability.

MEMSCAP provides micro-electro-mechanical systems (MEMS)-based products including components, component designs (IP), manufacturing and related services. More information at www.memscap.com.

View recent issues of the MEMS Direct newsletter

Researchers from North Carolina State University have developed the first functional oxide thin films that can be used efficiently in electronics, opening the door to an array of new high-power devices and smart sensors. This is the first time that researchers have been able to produce positively charged (p-type) conduction and negatively charged (n-type) conduction in a single oxide material, launching a new era in oxide electronics.

To make functional electronic devices, you need materials with a “p-n junction,” where the positively charged and negatively charged materials meet. Solid state silicon electronics achieved this decades ago, but are limited by the amount of power and temperature they can handle. Oxide materials are an attractive alternative to silicon because they can handle more power.

However, attempts to pair different p-type and n-type oxide materials previously ran into problems at the interface of the two materials – the p-n junction was always inefficient.

“We avoided this problem by using the same material for p- and n-type conduction,” says Dr. Jay Narayan, the John C. Fan Distinguished Chair Professor of Materials Science and Engineering at NC State and co-author of a paper describing the research. “This is a new era in oxide electronics.”

Specifically, Narayan’s team used lasers to create positively charged nickel oxide (NiO) thin films, then converted the top layer of those films to n-type. Because they could control the thickness of the n-layer, the researchers were able to control the depth and characteristics of the p-n junction. “This spatial and temporal selectivity provides unprecedented control to ‘write’ p-n junctions by laser beams and create ultra high-density device features for oxide electronics,” Narayan says.

By enabling the development of oxide electronics, the research allows for the creation of a host of new technologies in a wide array of fields. For example, because oxides can handle higher voltages than silicon-based electronics, the material could be used to create higher voltage switches for the power grid, which would allow more power to be transmitted on the existing infrastructure. Similarly, this would allow the development of sensors for use in higher-temperature environments, because oxides are more stable at high temperatures.

Oxide electronics could also be used to create new sensors for monitoring gases, since oxide materials can interact with oxygen. These sensors could have a variety of applications, including testing for air toxicity in security situations.

“These materials are also transparent,” Narayan says, “so this makes transparent electronics possible.”

The paper, “Controlled p-type to n-type conductivity transformation in NiO thin films by ultraviolet-laser irradiation,” is published online in the Journal of Applied Physics. The paper was co-authored by Pranav Gupta, a Ph.D. student at NC State; Narayan; and Drs. Titas Dutta and Siddhartha Mal, both former Ph.D. students at NC State now working at Intel. The research was funded by the National Science Foundation.

March 6, 2012 — AEPI–The Grenoble-Isere France Economic Development Agency and CEA-Leti will co-host a site visit to CEA-Leti and other facilities on the MINATEC campus, Grenoble, following MEMS Executive Congress Europe on March 23. AEPI and CEA-Leti are sponsors of the Congress, which takes place on March 20 in Zurich, Switzerland.

The Grenoble site visits on the MINATEC campus will include: the CEA-Leti showroom, the 200mm-wafer micro electro mechanical system (MEMS) line, the Clinatec/Nanobio facilities researching implanted micro-nanotechnologies, and an optional evening social event. The MINATEC innovation campus is home to 2,400 researchers, 1,200 students, and 600 technology transfer experts on a state-of-the-art 20-hectare campus offering 10,000 square meters of clean room space.

Grenoble-Isère is a major center for information and communication technologies, biotechnologies and new energy technologies. For more information about the CEA-Leti/Minatec site visit, please visit www.memsindustrygroup.org/grenoble.

On the tour:
CLINATEC is a clinical-preclinical research facility devoted to the validation of new implanted micro-nanotechnologies at the human brain interface, associating biological and imaging facilities to provide the best environment for the first preclinical and human proof of concept. Located at MINATEC, it was formed by CEA-Leti, Grenoble University Hospital and Joseph Fourier University.

Leti is an institute of CEA, a French research-and-technology organization with activities in energy, IT, healthcare, defence and security. Leti specializes in nanotechnologies and their applications, from wireless devices and systems, to biology, healthcare and photonics. NEMS and MEMS are at the core of its activities. CEA-Leti operates 8000m² of state-of-the-art clean room space on 200mm and 300mm wafer platforms. It employs 1,400 scientists and engineers and hosts more than 190 Ph.D. students and 200 assignees from partner companies.

MINATEC is a micro- and nanotechnology innovation campus uniting higher education, fundamental and applied research, industrial innovation, technological R&D infrastructures and investors. Visit: http://www.minatec.com/en

MEMS Executive Congress Europe brings together business leaders from automotive, industrial/energy, biomedical/quality of life, and consumer goods sectors to discuss designing and manufacturing MEMS technology and the use of MEMS in commercial applications. MEMS Executive Congress Europe is co-located with Smart Systems Integration. Visit www.memscongress.com for complete details.

The Grenoble-Isère Economic Development Agency/Agence d’Etudes et de Promotion de l’Isère, is entirely responsible for promoting Grenoble-Isère and capitalizing on its assets to attract new business. Website: http://www.grenoble-isere.com/eng/

View recent issues of the MEMS Direct newsletter

March 5, 2012 — New micro electro mechanical system (MEMS) thermopile players and applications are boosting market growth for infrared (IR) detectors, finds Yole Développement in its new report "Infrared Detector Market, Applications & Technology Trends."

Traditionally, a few players have dominated the business specially for motion detection: Perkin Elmer (which sold its IR detector branch that became Excelitas), Nicera, Murata, and Heimann. Some niche players (Pyreos, Irisys) have also developed innovative pyroelectric technologies (thin film, ceramic hybrid) that enable arrays of sensitive elements, but the volumes sold are still limited to niche markets (counting people, gas detection, spectroscopy).

Large MEMS manufacturers are entering the IR detector business: Texas Instruments, Omron, Panasonic, and Hamamatsu. These companies, boasting substantial revenues and resources, develop thermopile detectors manufactured on large MEMS production lines (6 to 8" wafers). This brings fab costs down, opening up new applications, like the temperature measurement function Texas Instruments (TI) supplies for notebooks, tablets, and other portable consumer electronics.

Figure. IR detector market forecast 2010-2016. SOURCE: Infrared Detector Market, Applications & Technology Trends report, January 2012, Yole Développement.

IR detectors enable motion detectors for applications like lighting controls and alarms. 150 million units were sold in 2010, with low average selling prices (<$1). This mature market will grow at a significant rate (CAGR 2010-2016 in value: +9%), driven by concern for energy savings in buildings, said Yann de Charentenay, senior analyst. IR detector technology will increasingly be used to automatically power on and off lighting, and home appliances such as HVAC and TVs.

IR detectors also are used for non-contact temperature measurement in human ear thermometers, industrial pyrometers, and other applications. They also can detect gas and fire, or analyze materials. Detectors in these applications can cost anywhere from a single dollar to tens of dollars each. These usage sectors are growing, offering robust non-contact measurement with a long lifetime. These applications use small detectors with 1-4 IR-sensitive elements that can be made with pyroelectric sensors or thermopile sensors.

Large detectors (from 16 x 16 to 64 x 64 pixels) are developed to obtain advanced person detection functionalities meaning it is possible to locate the position of a person precisely in a space, to identify immobile persons (not possible with motion sensors) or to monitor large areas. The end markets will be for home automation, healthcare, or security businesses. Pyroelectric, thermopile, and microbolometer technologies all suit this space. Pyroelectric and thermopiles are mature technologies, but for smaller detectors. Microbolometer technology is leading the 10K+ pixel resolution infrared imager business, at prices of several hundred dollars. Microbolometer players (Ulis, FLIR, NEC, DRS) have started to develop or investigate large detector applications, but the low cost target will present a challenge. Expect the dominant technology to emerge next year, forecasts Wenbin Ding, Technology & Market Analyst, MEMS Devices & Technologies.

Also read: Wafer-level packaging emerges for uncooled IR imagers

With the arrival of new MEMS players and the emergence of large detector applications, Yole Développement expects that the overall IR detector business will grow from $152 million in 2010 to $286M in 2016, a 5-year CAGR of 11%.

Companies cited in the report: 3S pocketnet, Agilent, Ametek, BAE , Bosch security, Cerberus, CSST, Delphi, Dias Infrared, DRS, Dostmann, E+e, Excelitas, FLIR, Fluke, Fuji Piezo, G&E, Hager, Hamamatsu, Heimann, Heitronics, Honeywell security, ICX FL IR, Infratec, Intex, Irisys, Korea digital, L3com, Land, Legrand, Leister Axetris, Lumasense ITC, Melexis, Memstech – Ann Arbor, Merten, Mitsubishi Electric, Murata, NEC Avio, Nicera, Omega, Omron, Panasonic, Perkin Elmer, Pyreos, Raytheon, Ritsumeikan University, Samsung, SCD, Schneider Electric, Selex galileo, Sensair, Senseair, Sensource, Shimadzu, Somfy, Sony, Symetrix, Telaire, Texas Instrument, Thermofisher, Tyco security, Tyndall, Ulis, UTC fire & security, Visonic, Winsen, Wuan Cubic, Yongsheng, ZB sensor.

Report authors:
Yann de Charentenay, Senior Analyst covers MEMS, materials and compound semiconductors.

Wenbin Ding is a Technology & Market Analyst at Yole Développement, specializing in MEMS Devices & Technologies.

Yole Développement is a group of companies providing market research, technology analysis, strategy consulting, media in addition to finance services. Access the report at www.yole.fr.

View recent issues of the MEMS Direct newsletter

March 5, 2012 — The Albany, NY-based College of Nanoscale Science and Engineering’s (CNSE) Smart System Technology and Commercialization Center of Excellence (STC), which performs micro electromechanical system (MEMS) and nanotechnology-enabled manufacturing and packaging, successfully completed the International Organization for Standardization’s (ISO) 9001:2008 registration.

The registration incorporates rigorous criteria in a collection of formal international standards, technical specifications and reports, as well as handbooks and web-based documents on quality management. CNSE’s STC worked with EEP Quality Group of Rochester to review and edit existing documentation, and to develop a number of new standard operating procedures in order to comply with ISO requirements.

With ISO 9001:2008, the MEMS development center expects to have "new opportunities to create high-tech jobs" and be able to "attract additional partners in the industrial and government sectors," including the Department of Defense and various intelligence agencies that require ISO certification, and domestic and foreign commercial companies, Dr. Alain E. Kaloyeros, CNSE SVP and CEO, said. Numerous enhanced security features are being put into place that will allow CNSE’s STC to heighten its site security clearance as well.

CNSE’s STC expects to hire additional employees as a result of its ISO registration. New hires will range from engineering and technical personnel to cleanroom operators, who will be needed to support both existing projects and new programs that transition from prototyping and pilot production to low- and mid-volume manufacturing.

The UAlbany CNSE is a college dedicated to education, research, development and deployment in the emerging disciplines of nanoscience, nanoengineering, nanobioscience and nanoeconomics. CNSE’s footprint spans upstate New York, including its Albany NanoTech Complex, an 800,000-square-foot megaplex with the only fully-integrated, 300mm wafer, computer chip pilot prototyping and demonstration line within 85,000 square feet of Class 1 capable cleanrooms. More than 2,700 scientists, researchers, engineers, students and faculty work here, from companies including IBM, Intel, GlobalFoundries, SEMATECH, Samsung, TSMC, Toshiba, Applied Materials, Tokyo Electron, ASML and Novellus Systems. An expansion now underway, part of which will house the world’s first Global 450mm Consortium, will add nearly 500,000 square feet of next-generation infrastructure, an additional 50,000 square feet of Class 1 capable cleanrooms, and more than 1,000 scientists, researchers and engineers from CNSE and global corporations. For information, visit www.cnse.albany.edu.

CNSE’s Smart System Technology and Commercialization Center of Excellence (STC) in Rochester, NY, offers state-of-the-art capabilities for MEMS fabrication and packaging. It assists small and large companies in transitioning new technologies from concept to manufacturing. STC maintains a 140,000-square-foot facility with over 25,000 square feet of cleanrooms for MEMS fabrication and packaging, and works with large and medium-sized companies to help them bring new technologies to market; with small companies ready to transition from prototype and low-volume manufacturing to scalable manufacturing; and with various federal agencies to develop technology solutions to areas of critical national need, including smart prosthetics and improvised explosive device (IED) detection. For more information, visit www.stcmems.com.

View recent issues of the MEMS Direct newsletter

March 2, 2012 – BUSINESS WIRE — Tessera Technologies Inc. (NASDAQ:TSRA), through its wholly owned subsidiary, DigitalOptics Corporation (DOC) will acquire certain assets of Vista Point Technologies, a Tier-One-qualified camera module manufacturing business of Flextronics International Ltd. (NASDAQ:FLEX). DOC anticipates that the business will have a capacity to manufacture approximately 50 million camera module units per year.

DOC will pay approximately $23 million in cash for the assets from Flextronics’s camera module business in Zhuhai, China, along with the equity interests of a wholly owned foreign enterprise that will own those assets, together called the Zhuhai Camera Module Business. It includes existing customer contracts and a lease to an approximately 135,000-sq.ft. facility.

Tessera’s strategy is to transform DOC from an optical and image enhancement software and components business into a Tier-One qualified, vertically integrated supplier of next-generation camera modules, said Young. Tessera estimates the market for mobile cameras at about $9 billion. Tessera is also involved with multiple Tier-One mobile phone OEMs regarding its micro electro mechanical system (MEMS) autofocus product, expecting a design win in H1 2012 and a volume manufacturing ramp in Q4. "Our goal is for DOC to become profitable in 2013," said Young.

Attend the free on-demand webcast: Lens Tilt in Small Auto-Focus Cameras from DigitalOptics

The Zhuhai Camera Module Business will enhance DOC’s existing collaborations with camera module makers by driving rapid market introduction of next-generation technology, said Robert A. Young, president and chief executive officer, Tessera Technologies, Inc., adding that Tier One OEM manufacturers require that camera modules be delivered through dual sourcing from high-volume manufacturing facilities. The Zhuhai Camera Module Business offers a world-class, cost-competitive, high-volume facility and a well-trained team of engineers and manufacturing employees. DOC plans to increase sales of its imaging technologies via the new assets, combining its MEMS autofocus and other proprietary technologies in integrated camera modules for mobile phones, said Bob Roohparvar, president of DigitalOptics Corporation.

DOC has been developing its capacity of oversee high-volume manufacturing operations alongside its technological development in optical imaging. DOC has hired more than a dozen executives and managers with engineering scale-up expertise and volume manufacturing experience.

Under the agreement, DOC will reimburse Flextronics for certain transaction expenses, taxes and inventory, the amounts of which will be determined at closing. The transaction also includes an intellectual property assignment and license agreement, and a transition services agreement. DOC intends to offer employment to a portion of the existing work force of the Flextronics camera module business in Zhuhai, China. The transaction is expected to close by the end of the third quarter. It is subject to various closing conditions, including necessary approvals from the appropriate PRC governmental authorities.

Tessera’s financial advisor on the transaction was GCA Savvian Advisors LLC, and its legal advisor was Latham & Watkins LLP.

Tessera Technologies, Inc. is a holding company with operating subsidiaries in two segments: Intellectual Property and DigitalOptics. Our Intellectual Property business generates revenue from patented innovations through license agreements with semiconductor companies and outsourced semiconductor assembly and test companies. Tessera, Inc. pioneered chip-scale packaging solutions for the semiconductor industry. Our DigitalOptics business delivers innovation in imaging and optics with products and capabilities that enable expanded functionality in increasingly smaller devices. Our miniaturized camera module solutions provide cost-effective, high-quality camera features, including micro electro mechanical systems (MEMS)-based autofocus, extended depth of field (EDoF), zoom, image enhancement and optical image stabilization. We also offer customized micro-optic lenses from diffractive and refractive optical elements to integrated micro-optical subassemblies. For information, go to www.tessera.com.

View recent issues of the MEMS Direct newsletter

March 1, 2012 – BUSINESS WIRE — After reporting Q4 2011 results, micro electro mechanical system (MEMS) supplier MEMSIC Inc. (NasdaqGM: MEMS) discussed its 2 main goals for 2012.

MEMSIC is pursuing more design wins with global customers in the growing mobile phone and consumer market, said chairman, president, and CEO Dr. Yang Zhao.

Secondly, the company is looking to leverage its MEMS sensor and sensor system integration technology to create more value-added products for consumer, industrial and automotive applications, Zhao said, noting MEMSIC’s ability to integrate MCU and software to create smart-sensing systems beyond sensor fusion.

In November 2011, a MEMSIC subsidiary formed a joint venture with Wuxi New District Science and Technology Financial Investment Group Co. Ltd., a state-owned Chinese venture capital fund, to bring MEMSIC’s mesh wireless sensor network technology to the sensor and sensing network solution market.

MEMSIC Inc. provides advanced semiconductor sensors and multi-sensor systems based on MEMS technology IC- and module-level integration technologies. The company’s shares are listed on the NASDAQ Stock Exchange (NASDAQ GM: MEMS). Learn more at www.memsic.com.

View recent issues of the MEMS Direct newsletter

March 1, 2012 — Gyroscopes generated more revenues in 2011 than any other consumer/mobile micro electro mechanical system (MEMS), thanks to enthusiastic adoption of Apple Inc. iPhone and iPad devices late in the year. This was the first time gyroscopes topped accelerometers in consumer/mobile MEMS revenues, reports IHS.

Gyroscopes netted $655.4 million in 2011, up 66% from $394.5 million in 2010. The devices will bring in $1.1 billion by 2015, maintaining a lead over accelerometers ($705 million by 2015).

Figure. Worldwide gyroscope MEMS revenue forecast in consumer/mobile MEMS sector. SOURCE: IHS iSuppli Research, March 2012.

Of all consumer/mobile motion sensors in 2011, 41% were gyroscopes, by revenue, up from 24% in 2010. The total mobile motion sensor market hit $1.6 billion, up from $1.1 billion the prior year.

3-axis gyroscopes, used mostly in tandem with 3-axis accelerometers, are enabling more accurate motion sensing. Gyroscopes improve the motion-based interface, and can provide optical image stabilization and navigation-related functions. "Of the $655 million total revenue generated by the gyroscope space, the 3-axis segment accounted for $462 million, 71%," in 2011, said Jérémie Bouchaud, director and senior principal analyst for MEMS & sensors at IHS. Apple, with its smartphone (iPhone) and tablet (iPad) products, was the main consumer, buying 62% of 3-axis gyroscopes.

STMicroelectronics was the leading producer of both gyroscopes and accelerometers. Apple accounts for half of ST’s MEMS business, and the company is the sole source for gyroscopes and accelerometers for the iPhone and iPad.

Combo packages of 3-axis accelerometers and gyroscopes — 6-axis inertial measurement units (IMU) — will dominate in the sales of 3-axis gyroscopes by 2014. "Surprisingly compact" 6-axis compass modules (compass + accelerometer) are coming to market now, as are 9-axis IMUs with 3-axis electronic compasses added to 6-axis IMUs. Bosch Sensortec and InvenSense have introduced a 6-axis compass module and a 9-axis IMU, respectively.

In general, motion sensors like gyroscopes, accelerometers and electronic compasses will continue to rule consumer and mobile MEMS, the largest segment of an industry that includes other MEMS sectors such as automotive, medical, industrial, and aerospace and defense. Aside from smartphones and tablets, expect to find consumer-app motion sensors in TV remote controls and ultrabook laptops. By 2015, both TV remote control and ultrabook applications will add another $155 million in revenue derived from the use of accelerometers, gyroscopes and electronic compasses, up from $9 million in 2011.

Intel is recommending accelerometers, gyroscopes, electronic compasses and even pressure sensors for its ultrabooks, although some combinations will only be seen in convertible ultrabooks — those with a screen that can be flipped back to form a tablet.

MEMS microphones, also appearing in Apple’s mobile electronics, saw rapid growth in 2011. Apple uses two analog MEMS microphones in the iPhone 4 and 4S (MEMS mics provide voice suppression with Siri), along with one MEMS microphone in the headset that is sold with the phone. In addition, one digital MEMS microphone is present in the iPad 2. Revenue in 2011 for MEMS microphones reached $373 million, up 67% from $223 million in 2010.

Also read: Apple buys most MEMS microphones in 2011

Knowles Electronics still dominates the MEMS microphone sphere, but its share of shipments in the overall market has fallen from 88% in 2010 to 75% last year. There are now 8 suppliers producing more than 10 million MEMS microphone units each.

MEMS oscillators recently saw a surge of interest, with the entry of 3 big players. Murata, an established supplier of ceramic oscillators, acquired VTI Technologies in October last year. IDT, the leading manufacturer of complementary metal-oxide-semiconductor (CMOS) timing devices, introduced its first MEMS timing product in November. NXP, a supplier of real-time clocks, brought its MEMS timing debut to the Consumer Electronics Show in January 2012.

Read the IHS report, Consumer MEMS Continue to Thrive on Smartphones, Tablets and Ultrabooks, at http://www.isuppli.com/MEMS-and-Sensors/Pages/Consumer-MEMS-Continue-to-Thrive-on-Smartphones-Tablets-and-Ultrabooks.aspx?PRX

View recent issues of the MEMS Direct newsletter

February 29, 2012 — Nanolab Technologies Incorporated inaugurated its 47,000sq.ft. state-of-the-art facility in Milpitas, CA on "Leap Day" as a nod to the company’s "Giant Leap Forward" theme for 2012. The new facility more than doubles Nanolab Technologies’ space.

Nanolab Technologies provides electron microscopy, surface analysis and failure analysis services for MEMS and IC design, process control, and fabrication issues.

The new state-of-the-art laboratory was designed to maximize the performance of extremely high resolution instruments, with precision temperature control, vibration isolation, acoustical absorption, and an electrical system design to virtually eliminate electrical and magnetic field interference (EMI), and environmental and mechanical influences. This supports expansion into new analytical service sectors, said president and CEO John Traub.

The Chiller-based Radiant Cooling System was designed and built to achieve precise temperature control that eliminates lab temperature variances. The system controls and redirects airflow to prevent turbulence that can compromise instrument performance.

The web-based Environmental Control System facilitates remote reprogramming and control of individual lab environments to precondition and stabilize operating conditions prior to the arrival of laboratory analysts. This is particularly valuable when responding to a customer emergency call at night or on weekends, when all environmental systems are optimized for minimizing energy consumption and reducing operating costs.

The new laboratory is designed around a central facilities Service Module "spine" featuring double-wall construction and three layers of high-efficiency acoustical absorption material. This is the central support core for all laboratories and houses ancillary equipment and control delivery systems for gases and fluids. All major mechanical systems are installed on an exterior isolated equipment pad.

The facility was also designed to accommodate seamless expansion with facilities in place for new laboratories as the company grows and adds new instruments, techniques and analytical services.  
 
Nanolab Technologies is a testing laboratory providing chip designers, equipment OEMs and integrated circuit fabricators with independent assessments of IC design, process control, and fabrication issues. For further information, visit www.nanolab1.com.

View recent issues of the MEMS Direct newsletter

MIT designs completely 3D MEMS


February 29, 2012

February 29, 2012 — MIT researchers have come up with a new approach to micro electro mechanical systems (MEMS) design that enables engineers to design 3D configurations, using existing fabrication processes. With this approach, the researchers built a MEMS device that enables 3D sensing on a single chip.

The silicon device, not much larger than Abraham Lincoln’s ear on a U.S. penny, contains microscopic elements about the width of a red blood cell that can be engineered to reach heights of hundreds of microns above the chip’s surface.

Fabio Fachin, a postdoc in the Department of Aeronautics and Astronautics, says the device may be outfitted with sensors, placed atop and underneath the chip’s minuscule bridges, to detect three-dimensional phenomena such as acceleration. Such a compact accelerometer may be useful in several applications, including autonomous space navigation, where extremely accurate resolution of three-dimensional acceleration fields is key.

“One of the main driving factors in the current MEMS industry is to try to make fully three-dimensional devices on a single chip, which would not only enable real 3-D sensing and actuation, but also yield significant cost benefits,” Fachin says. “A MEMS accelerometer could give you very accurate acceleration [measurements] with a very small footprint, which in space is critical.”

Fachin collaborated with Brian Wardle, an associate professor of aeronautics and astronautics at MIT, and Stefan Nikles, a design engineer at MEMSIC, an Andover, Mass., company that develops wireless-sensor technology. The team outlined the principles behind their 3-D approach in a paper accepted for publication in the Journal of Microelectromechanical Systems.

While most MEMS devices are two-dimensional, there have been efforts to move the field into 3-D, particularly for devices made from polymers. Scientists have used lithography to fabricate intricate, three-dimensional structures from polymers, which have been used as tiny gears, cogs and micro-turbines. However, Fachin says, polymers lack the stiffness and strength required for some applications, and can deform at high temperatures — qualities that are less than ideal in applications like actuators and shock absorbers.

By contrast, materials such as silicon are relatively durable and temperature-resistant. But, Fachin says, fabricating 3-D devices in silicon is tricky. MEMS engineers use a common technique called deep reactive ion etching to make partially 3-D structures, in which two-dimensional elements are etched into a wafer. The technique, however, does not enable full 3-D configurations, where structures rise above a chip’s surface.

To make such devices, engineers fabricate tiny two-dimensional bridges, or cantilevers, on a chip’s surface. After the chip is produced, they apply a small force to arch the bridge into a three-dimensional configuration. This last step, Fachin says, requires great precision.

Instead, the MIT team came up with a way to create 3-D MEMS elements without this final nudge. The group based its approach on residual stress: In any bridge structure, no matter its size, there exist stresses that remain in a material even after the original force needed to produce it — such as the heat or mechanical force of a fabrication process — has disappeared. Such stresses can be strong enough to deform a material, depending on its dimensions.

Fachin and his colleagues studied previous work on microbeam configurations and developed equations to represent the relationship between a thin-film material’s flexibility, geometry and residual stress. The group then plugged their desired bridge height into the equations, and came up with the amount of residual stress required to buckle or bend the structure into the desired shape. Fachin says other researchers can use the group’s equations as an analytical tool to design other 3-D devices using pre-existing fabrication processes.

“This offers a very cost-effective way for 3-D structures,” says Y.K. Yoon, an associate professor of electrical and computer engineering at the University of Florida who did not take part in the research. “Since the process is based on a silicon substrate, and compatible with standard complementary metal oxide semiconductor (CMOS) processes, it will also offer a pathway to a smart CMOS-MEMS process, with good manufacturability.”

The group used their analytical tool to design tiny 3-D devices out of a composite silicon structure, with each chip containing highly curved or buckled microbeams. Fachin’s sensors, placed on top of each bridge and on the surface of the chip, can triangulate to measure acceleration.

“For other applications where you want to go much larger in size, you could just pick a material that has a larger residual stress, and that would cause the beam to buckle more,” Fachin says. “The flexibility of the tool is important.”

Learn more at www.mit.edu.