biomedical devices

MEMS technology has changed human interaction with electronic devices. Introduced in the 1990s, the first mass-market MEMS devices were used for inkjet printheads and automotive airbag crash sensors. Today, MEMS are ubiquitous, with billions of the tiny devices adding intelligence and interactivity to smartphones, smart speakers, wearables, automobiles, biomedical devices, remote monitoring and event detection systems, and countless other applications. Integrating MEMS with Flexible Hybrid Electronics (FHE) is an important step in the evolution of this miniaturized intelligent sensing technology, paving the way for its use in new classes of flexible, conformal devices.The integration of the two technologies promises to breed new applications in small form factors but also presents challenges inherent to FHE design and fabrication processes. SEMI’s Nishita Rao caught up with Nathan Pretorius, prototyping and automation engineer, NextFlex, to discuss MEMS-FHE device integration challenges and opportunities ahead of his February 26 presentation, Integrating MEMS Devices in FHE, at FLEX|MEMS Sensors Technical Congress (MSTC) 2020, February 24-27, 2020, at the DoubleTree by Hilton in San Jose, California.Join us at FLEX|MSTC to meet Nathan and other industry influencers advancing innovation in FHE and MEMS sensors. Register now to connect with him at FLEX|MSTC or visit him on LinkedIn.SEMI: Why is integrating MEMS devices into FHE systems important? What new use cases might it enable?Pretorius: The main value proposition of integrating MEMS devices into FHE is that it allows MEMS devices to exist in a different form factor than was possible previously, giving us high-quality MEMS sensors on the flexible and conformable platform of FHE.Ease of application, flexibility, lower cost and rapid iteration on a design are just some of the benefits of FHE devices. And because there are few robust FHE sensors that overlap with MEMS’ capabilities, when you combine the two, you get a lot of compelling uses. That’s why NextFlex is working with agencies and companies to evaluate MEMS’ integration, including using bare MEMS die with microfluidics and promoting new ways of attaching and packaging MEMS die for use with FHE. SEMI: Why is FHE an ideal platform for integrating various types of sensors?Pretorius: MEMS integrated with FHE devices are ideal for rapid design and deployment of data-gathering sensor nodes — which we can iterate for specific applications. A few examples include on-body health monitoring devices for bio-fluids analysis, medical pressure sensors for monitoring blood pressure, and peel-and-stick sensors nodes for infrastructure monitoring. In terms of design and production, FHE devices support rapid prototyping, allowing for instantaneous design-iteration cycles. This speeds design-to-production over traditional rigid PCBs and copper flex because the feedback cycle time between design, manufacturing and testing is shorter, accelerating time to market. What’s exciting about FHE technology is that a variety of sensors or components, including MEMS, can be designed into the base system to easily customize it for a specific application. In addition, our experience shows that when compared to a traditional rigid PCB, an FHE board reduces manufacturing steps and device weight by two-thirds and, perhaps most importantly, converts the device to a thin, conformal shape that makes possible products in new form factors. SEMI: What are the primary challenges to integrating MEMS with FHE? What is NextFlex doing to help device manufacturers address these challenges? Pretorius: There are a few challenges, some of which are device-specific. Most recently, I’ve been focusing on inertial and timing devices, including accelerometers, gyroscopes and resonators. There are a few technical challenges involved in the process of getting the devices from the wafer to an FHE substrate. The wafer processing is very important, especially the dicing and thinning steps. After thinning and dicing, the die is placed onto the FHE substrate. The stresses caused by bonding to the substrate have to be understood and characterized. After placing the die, you then have a calibration step, which is normally performed after the device is packaged. With a MEMS die placed onto directly onto an FHE substrate, calibration then must be done.Finally, the device encapsulation is important, since on an FHE substrate the hard-to-soft material transition is very important to mitigate stresses to rigid component interfaces. We have also been looking at how to work with devices that have damping vents. Flexible encapsulants are inherently more permeable to gases and water vapor than hard encapsulants, so studying the encapsulation of MEMS devices on FHE is another area of interest. NextFlex has been working in a supporting role to evaluate best design practices and best attach and integration methods. In addition to our ongoing collaborative programs, NextFlex is developing the FHE manufacturing ecosystem to include system and component manufacturers and designers, product developers, and materials and equipment providers.SEMI: How do we facilitate closer collaboration between the FHE manufacturing ecosystem and MEMS suppliers such as MEMS device manufacturers, product developers, and materials and equipment providers?Pretorius: It’s important to include manufacturers early in the design process so we can identify challenges up front. That’s why NextFlex spearheads technology road-mapping efforts that include representatives from across the manufacturing ecosystem. We use the roadmaps to prioritize challenges that we can address effectively through collaboration, focusing the industry on solving problems through Project Calls that reveal integration challenges and results from real devices and that tell us how the materials and equipment actually perform with a real device.NextFlex keeps the information flowing, holding quarterly project update webinars to share results. As current devices are optimized for the process in which they will be used, we learn a lot from the project performers who make FHE system demonstrators — and we share that information with the member community. SEMI: Can you point to an example of a successful MEMS-FHE device integration?Pretorius: MEMS-FHE integration is still in the early stages, but we are working on several projects including a DARPA Seedling project for which we have integrated MEMS sensors into FHE systems for testing and evaluation. We plan to continue this work by integrating MEMS and FHE devices using methods that support mass production.SEMI: What would you like FLEX|MSTC attendees to take away from your presentation?Pretorius: We would like to see the FHE community work more closely with MEMS device manufacturers. For example, NextFlex often works with manufacturers to gain access to bare die, which is still a significant hurdle in making devices.The best way to speed things along is to get involved. We encourage FLEX|MSTC attendees to join NextFlex. As a prototyping and automation engineer at NextFlex, Nathan Pretorius explores new print methods for prototyping and automation using novel materials and processes. Pretorius currently focuses on how best to apply software scripting and machine learning to streamline FHE processes. Prior to joining NextFlex, he researched the strengths of roll to roll and screen printing on printed electronics designs, including capacitive touch interfaces, FHE passive component design, and antennas. Nathan holds a Bachelor of Science degree in Graphic Communications from Clemson University. FLEX|MSTC is organized MEMS Sensors Industry Group (MSIG) and FlexTech, SEMI technology communities focused on the growth of MEMS sensors and the flexible electronics supply chain, respectively.Nishita Rao is marketing manager for technology communities at SEMI.

The BioMEMS market is becoming increasingly diverse, encompassing gas and pressure sensors, ultrasound, specialized biomedical sensors, and other types of MEMS and microfluidic chips used for drug delivery and analytical applications. The BioMEMS market is also growing steadily: Research firm Yole Développement predicts that BioMEMS will grow at 14.9% CAGR from 2017-2023, reaching US$6.9B by 2023.1 As a high-value market, BioMEMS is worth pursuing as long as you can manage the complexities of manufacturing, including a sometimes-fragmented supply chain. Fortunately, the MEMS manufacturing ecosystem is evolving to accommodate the needs of companies that are in the process of commercializing BioMEMS-enabled products. Understanding the ecosystem’s shifting dynamics will help BioMEMS to flourish in this promising while often-challenging market segment.Unique Product, Unique ProcessIn the world of semiconductor manufacturing, it is routine for a fab to manufacture hundreds of different device designs using just a handful of process nodes. Semiconductor foundries share their design rules with customers, who then develop the mask set accordingly, literally adapting their designs to fit the rules for manufacturing on one of the foundries’ process nodes. In stark contrast, most MEMS devices cannot conform to the level of standardized manufacturing processes that work so well for semiconductors. Rather, MEMS challenges us to develop individualized processes for each device. It’s one product, one process.New BioMEMS designs generally emerge from either corporate R D or academia, two groups that approach specialized MEMS foundries such as ours when they’re entering pilot or low-volume production. Today successful commercialization depends on open, accurate communication and close collaboration. MEMS foundries must work side-by-side with designers to ensure that designs are based on real-world manufacturing process technologies. This highly customized manufacturing model makes it very difficult to support future demand for the groundswell of diverse BioMEMS devices that are in development. If we want to handle this upward trajectory of BioMEMS, we’ll need to adapt.Change the ModelWhile most existing MEMS foundries currently support a wide variety of devices types, I predict that market forces will cause our foundries to move toward specialization. Some companies will specialize in what they already do best, e.g., inertial sensors for the automotive industry. Others might choose to develop their foundry business around a purpose-built facility, which, for example, only manufactures microfluidics or magnetic devices. Larger enterprises might opt to build captive foundries that are designed to serve their specific needs. Get Creative: Combine, CollaborateSatisfying the thriving market for BioMEMS will require creativity. One idea: combine different disciplines of the manufacturing process at the same foundry. For example, we could have a biochemistry fab and a MEMS fab under the same roof, or we could have a MEMS fab and a packaging facility in one building. While these approaches may not yet exist outside of academia, necessity may drive them to fruition.It will also require heightened strategic collaboration, a process that has already begun. To support both large volumes and greater diversity of devices, some MEMS foundries are building cooperative relationships with former competitors. Think of it as a restructuring of the supply chain.Embracing the special challenges of BioMEMS manufacturing is worth our investment in time and resources. We need to step back, individually and collectively, to understand where each of the existing MEMS foundries fits into the new supply chain so we can leverage our strengths. We can start by forging stronger alliances for tech transfer. Once we more freely share information as we engage in joint product development — involving technology teams who are more connected and less guarded — we will expedite tech transfer and manufacturability.While we are unlikely to achieve the same level of standardization that has enabled the semiconductor industry to reach its great heights, as long as we evolve to meet demand, we will grow together and prosper.To learn more about this topic, meet with Jessica Gomez at the upcoming SEMI-MSIG MEMS Sensors Executive Congress (October 22-24, 2019 in Coronado, Calif.) or email her: [email protected][1] “BioMEMS Emerging Non-Invasive Biosensors: Microsystems for Life Sciences Healthcare 2018 Report,” Yole Développement, https://yole-i-micronews-com.osu.eu-west-2.outscale.com/uploads/2018/08/Sample-BioMEMS-Non-Invasive-Sensors-Microsystems-for-Life-Sciences-Healthcare-2018-.pdf As founder and CEO of Rogue Valley Microdevices, Jessica Gomez has created a world-class precision MEMS foundry and wafer fab in the heart of Southern Oregon. Integral to her role as CEO, Ms. Gomez practices a business philosophy of offering custom design, best-in-class process technology and R D expertise to customers, to help them achieve the highest quality and reliability in their products.In 2018, Ms. Gomez was selected for the prestigious SEMI Board of Industry Leaders. SEMI also recognized her in its first Spotlight on SEMI Women, which honors accomplished women in the global microelectronics industry.Prior to founding Rogue Valley Microdevices in 2003, Ms. Gomez honed her experience in semiconductor processing and production management through positions at Standard Microsystems Corporation, Integrated Micromachines and Xponent Photonics.For more information, visit: https://roguevalleymicrodevices.com/Rogue Valley Microdevices is a longtime member and supporter of SEMI-MEMS Sensors Industry Group, which connects the MEMS and sensors supply network, allowing members to address common industry challenges and explore new markets.