PZT

When developing industry forecasts, market analysts gather data from hundreds of companies to provide actionable insights on established technologies and to identify near-term business opportunities. As a developer of new MEMS and sensor technologies for a range of commercial applications, clients often ask us, “What’s going to be hot?” Gauging the promise of emerging technologies that are five to 10 years from commercialization requires taking a different tack.History tells us that most of today’s blockbuster MEMS products were born as academic research projects. Years of hard work by entrepreneurs, funded by millions of dollars, have turned proof-of-concept research into new commercial products. To identify up-and-coming technologies, we gather information straight from the source: academic conferences and articles.Chirp Microsystems is a good proof point of our research methodology: In my 2012 report on emerging technologies, I highlighted research from UC Berkeley and UC Davis on “In-Air Ultrasonic Rangefinding and Angle Estimation Using an Array of AlN Micromachined Transducers.” Soon after publication, the authors incorporated Chirp Microsystems to commercialize their technology for gesture- and fingerprint-recognition applications.After five years of development work, Chirp’s products are entering the marketplace. In February 2018, the global supplier TDK InvenSense acquired Chirp, underscoring the company’s commercial potential. At October’s SEMI-MSIG MEMS Sensors Executive Congress in Napa, Calif., Chirp’s CEO, Dr. Michelle Kiang, held attendees rapt as she described her company’s journey from startup to wholly owned subsidiary.There’s a methodThis year, I reviewed over 100 papers from top researchers presenting noteworthy technologies at the Hilton Head Workshop on Solid-State Sensors, Actuators and Microsystems. My criteria for selection were: commercial relevance; offers a solution to a known or anticipated problem; and technology game-changers. The following caught my eye: Event-driven sensors: Cleverly designed silicon MEMS that consume no power while standing by. A triggering mechanical or thermal event closes a contact within the sensor to activate its circuitry and telemetry. These sensors leverage existing fabrication methods, so they could become commercial products within five years for event monitoring and security applications. (UT Dallas, Northeastern University). Figure: 5-bit accelerometer having zero standby power. The device is open circuit until a threshold acceleration closes a mechanical contact. Source: University of Texas at Dallas. Thin film piezoelectric resonators: Advances in PZT deposition methods and process integration with CMOS were used to create monolithic acoustic waveguides for RF filtering in 5G applications. This new filter design, using existing scalable processes, is ripe for commercialization. (Purdue University, Texas Instruments) Intra-body communications: MEMS ultrasound transceivers, made from aluminum nitride, can send data directly through flesh at Mbit/s data rate. With trends toward networks of multiple implanted or wearable medical devices, this innovation would enable medically safe, secure, intra-body wireless communication. This early-stage work still needs in vivo validation and would likely require 10 or more years for development and regulatory approval. (Northeastern University) Screen- and 3D-printed sensors: One example of many exciting innovations using screen- and 3D-printing are potentiometric nitrate soil sensors. Low-cost and biodegradable, these sensors could be spread over huge areas to monitor a farm’s soil quality. Table-top and hobbyist tools are currently used to make screen- and 3D-printed devices, so new manufacturing equipment and infrastructure must be developed before commercial production could occur. (Purdue University) Biodegradable batteries: A paper-based battery that can deliver 0.5 uW of power, ingeniously using bacterial metabolism as the electrolyte. These batteries dissolve in water and could one day be used to power temporary medical implants or biodegradable sensors. This exciting proof-of-concept prototype will require significant process development and new manufacturing infrastructure for commercialization. (SUNY Binghamton) Figure: Paper-based battery dissolves in 60 minutes after immersion in water. Source: SUNY Binghamton To read more about these technologies, please download my presentation from SEMI-MSIG’s MEMS Sensors TechXpot at SEMICON West 2018.Alissa M. Fitzgerald, Ph.D., is the founder and managing member of A.M. Fitzgerald Associates, LLC, a MEMS and sensors development company in Burlingame, CA. She has over 20 years of engineering experience in MEMS design, fabrication and product development and now advises clients on the entire cycle of product development, from business and IP strategy to manufacturing operations. She is a frequent speaker at industry conferences and currently serves as a director of the Transducer Research Foundation, sponsor of the Hilton Head Workshop. She received her bachelor’s and master’s degrees from MIT and her doctorate from Stanford University in Aeronautics and Astronautics.For more information, visit: www.amfitzgerald.com

For medtech applications to flourish, sensors need a supporting infrastructure that translates the data they harvest into actionable insights, says Qualcomm Life director of business development Gene Dantsker, who will speak about the future of digital healthcare in the Medtech program at SEMICON West. “Rarely can one device give a complete diagnosis,” he notes. “What’s missing is the integration of all the sensor data into prescriptive information.” The maturing medtech sector has developed to the point where sensors can now capture massive amounts of data, conveniently collected from people via mobile devices. The sector now has higher compute capacity to process the data, and improving software can produce actionable insight from the information. The next challenge is to seamlessly integrate these components into legacy medical systems without disrupting existing workflow. “Doctors and nurses don’t have time for disruptive technology – a new system has to be invisible and frictionless to use, with one or fewer buttons, no training and truly automatic Bluetooth-like pairing,” he says. “So device makers need to pack all system intelligence into the circuits and software.”Getting actionable healthcare information from sensors requires integration into the existing medical infrastructure. Source: Qualcomm LifeOne interesting example is United Healthcare’s use of the Qualcomm Life infrastructure to collect data from the fitness trackers of 350,000 patients. The insurance company then pays users $4 a day, or ~$1500 a year, for standing, walking six times a day and other behaviors that clinical evidence shows will both improve patient health and reduce healthcare costs. “It’s a perfect storm of motivations for all stakeholders,” he says.Next hot MEMS topics: Piezoelectric devices, environmental sensors, near-zero power standbyWith sensor technology continuing to evolve, look for coming innovations in MEMS in piezoelectric devices, environmental sensors and near zero-power standby devices, says Alissa Fitzgerald, Founder and Managing Member of A.M. Fitzgerald and Associates, who will provide an update on emerging sensor technologies in the MEMS program at SEMICON West.Piezoelectric devices can potentially be more stable and perhaps even easier to ramp to volume than capacitive ones, with AlN devices for microphones and ultrasonic sensors finding quick success. Now the maturing infrastructure for lead zirconate titantate (PZT) is enabling the scaling of production of higher performing piezo material with thin film deposition equipment from suppliers like Ulvac Technologies and Solmates and in foundry processes at Silex and STMicroelectronics, she notes.In academic research, where most new MEMS emerge, market interest is driving development of environmental sensors and zero-power standby devices. With demand for environmental monitoring growing, much work is focusing on technologies that improve the sensitivity, selectivity and time of response of gas and particulate sensors. Research and funding is also focusing on zero or near-zero power standby sensors, using open circuits that draw no power until a physical stimulus such as vibration or heat wakes them up.MEMS, however, likely won’t find as much of a market in autonomous vehicles as once thought. “While the automotive sensor market will need many optical sensors, MEMS players are competing with other optical and mechanical solutions,” says Fitzgerald. “And here the usual MEMS advantage of small size may not matter much, and the devices will have to meet the challenging automotive requirements for extreme ruggedness.”Paula Doe, SEMI