Researchers at MIT developed a MEMS device that enables 3-D sensing on a single chip by using a new design approach. Their new design method uses existing fabrication processes and the silicon device may be outfitted with sensors, placed atop and underneath the chip’s minuscule bridges, to detect three-dimensional phenomena such as acceleration.
Microelectromechanical systems, or MEMS, are small devices with huge potential. Typically made of components less than 100 microns in size — the diameter of a human hair — they have been used as tiny biological sensors, accelerometers, gyroscopes, and actuators.
For the most part, existing MEMS devices are two-dimensional, with functional elements engineered on the surface of a chip. It was thought that operating in three dimensions — to detect acceleration, for example — would require complex manufacturing and costly merging of multiple devices in precise orientations.
Now researchers at MIT have come up with a new approach to MEMS design that enables engineers to design 3-D configurations, using existing fabrication processes; with this approach, the researchers built a MEMS device that enables 3-D 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.
Moving to 3-D
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.”