New technique offers precise, durable control over tiny mirrors or stages.
Microelectromechanical systems, or MEMS, are tiny machines fabricated using equipment and processes developed for the production of electronic chips and devices. They’ve found a wide variety of applications in today’s consumer electronics, but their moving parts can wear out over time as a result of friction.
A new approach developed by researchers at MIT could offer a new way of making movable parts with no solid connections between the pieces, potentially eliminating a major source of wear and failure.
The new system uses a layer of liquid droplets to support a tiny, movable platform, which essentially floats on top of the droplets. The droplets can be water or some other fluid, and the precise movements of the platform can be controlled electrically, through a system that can alter the dimensions of the droplets to raise, lower, and tilt the platform.
The new findings are reported in a paper in Applied Physics Letters, co-authored by Daniel Preston, an MIT graduate student; Evelyn Wang, the Gail E. Kendall Associate Professor of Mechanical Engineering; and five others.
A new approach to microelectromechanical systems (MEMS), developed by a team of researchers at MIT, could offer a new way of making movable parts with no solid connections between the pieces, potentially eliminating a major source of wear and failure. Video: Melanie Gonick/MIT
Preston explains that the new system could be used to make devices such as stages for microscope specimens. The focus of the microscope could be controlled by raising or lowering the stage, which would involve changing the shapes of supporting liquid droplets.
The system works by altering the way the droplets interact with the surface below them, governed by a characteristic known as the contact angle. This angle is a measure of how steep the edge of the droplet is at the point where it meets the surface. On hydrophilic, or water-attracting, surfaces, droplets spread out nearly flat, producing a very small contact angle, while hydrophobic, or water-repelling, surfaces cause droplets to be nearly spherical, barely touching the surface, with very large contact angles. On certain kinds of dielectric surfaces, these qualities can be “tuned” across that whole range by simply varying a voltage applied to the surface.
As the surface gets more hydrophobic and the droplets get rounder, their tops rise farther from the surface, thus raising the platform — in these tests, a thin sheet of copper — that floats on them. By selectively changing different droplets by different amounts, the platform can also be selectively tilted. This could be used, for example, to change the angle of a mirrored surface in order to aim a laser beam, Preston says. “There are a lot of experiments that use lasers, that could really benefit from a way to make these small-scale movements.”
The new system could be used to make devices such as stages for microscope specimens. The focus of the microscope could be controlled by raising or lowering the stage, which would involve changing the shapes of supporting liquid droplets. (Image: Daniel Preston/Device Research Lab)
In order to maintain the positioning of the droplets rather than letting them slide around, the team treated the underside of the floating platform. They made the overall surface hydrophobic, but with small circles of hydrophilic material. That way, all the droplets are securely “pinned” to those water-attracting surfaces, keeping the platform securely in position.
In the group’s initial test device, the vertical positioning can be controlled to within a precision of 10 microns, or millionths of a meter, over a range of motion of 130 microns.
MEMS devices, Preston says, “often fail when there’s a solid-solid contact that wears out, or just gets stuck. At these very small scales, things break down easily.”
While the basic technology behind the alteration of droplet shapes on a surface is not a new idea, Preston says, “nobody has used it to move a stage, without any solid-solid contact. The real innovation here is being able to move a stage up and down, and change its angle, without any solid material connections.”
In principle, it would be possible to use a large array of electrodes that could be adjusted to move a platform across a surface in precise ways, in addition to up and down. For example, it could be used for “lab on a chip” applications, where a biological sample could be mounted on the platform and then moved around from one test site to another on the microchip.
He says the system is relatively simple to implement and that it would be possible to develop it for specific real-world application fairly rapidly. “It depends how motivated people are,” he says. “But I don’t see any huge barriers to large-scale use. I think it could be done within a year.”
“Controlled movements of a stage in microscale are difficult, because the miniature versions of the familiar motors and gear mechanisms do not exist, and if they existed, they would be too weak and frictional, respectively,” says Chang-Jin Kim, a professor of mechanical and aerospace engineering at the University of California at Los Angeles, who was not involved in this research. “Since this challenge is rather fundamental, it is only logical (albeit exotic) to use liquid droplets as a mechanical element,” he says. “There are numerous questions remaining before this stage becomes practical, but this is a good start proving the main design concept.”
“This approach is simpler and hence is expected to provide a significant cost benefit over existing techniques in practical applications,” says Prosenjit Sen, an assistant professor at the Centre for Nano Science and Engineering at the Indian Institute of Science, who also was not involved in this work. “The use of droplet supports additionally provides some degree of vibration isolation, which is not possible in all-solid stages.”
The research team included MIT graduate students Ariel Anders and Yangying Zhu, Research Affiliate Banafsheh Barabadi, alumna Evelyn Tio ’14, and undergraduate student DingRan Dai. The work was supported by the Office of Naval Research and the National Science Foundation.
David L. Chandler on 16th of December 2016
MIT News Office
Source: MIT news