Miniature pop-up devices can stand up to extreme pressures, study says

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Miniature devices, notably those that bulge out from 2D surfaces like pop-up greeting cards, have seamlessly found their way into pressure-sensing and energy-harvesting technologies because of their ability to be frequently stretched, compressed or twisted. Despite their force-bearing abilities, it is still unclear if repeated physical stress can damage the working of these miniature devices, particularly if there is already a defect in their construction.

Using tiny pressure-sensing structures shaped like tables, Texas A&M University researchers have found that repeated pushes on the tables’ flat surface do not cause the structures to fall apart, even when the compressive forces are extreme. Instead, these tiny devices, including those with slight defects, were resilient, continuing to remain functional by bending their legs in proportion to the applied force.

The researchers said their findings, published in the February issue of the journal Extreme Mechanics Letters, have direct implications on the longevity of technologies that incorporate miniature devices, like soft wearable electronics, stretchable solar cells and pressure-sensing socks.

Miniature devices, like pressure sensors, need to faithfully convey the strength and a change in compressions. For many applications, sensors need to be very small to capture changes in pressure at a high enough resolution. Thus, miniature devices based on the Japanese paper-cutting and folding technique of kirigami offer an excellent solution.

Borrowing the principles of kirigami, a design of the miniature device is first etched on a 2D surface. Then, an inward push from the design boundary makes the structure pop up. Other times, the 2D print is stretched or twisted to reveal a more intricate 3D design. Regardless of the final use, kirigami-based devices must face continuous distortions to their shape, a phenomenon engineers refer to as deformation.

“Part of the appeal of using kirigami structures is that they can be repeatedly deformed for extended periods of time,” said Andreas A. Polycarpou, professor and department head in the J. Mike Walker ’66 Department of Mechanical Engineering. “But any kind of imperfection in these structures might impact their final performance, that is, their ability to be continuously deformed.” 

To investigate how defects might influence the function of kirigami devices, Polycarpou’s team, led by Kian Bashandeh, a graduate student in the College of Engineering and a primary author of the study, designed a set of experiments using tiny pressure sensors. Consisting of a flat surface supported by four legs, these structures buckle if pressure is applied from above.

For their study, the researchers repeatedly pressed down on the table-like structures using a diamond flat punch probe. Their sample included structures with slight defects, such as a small crack on one of the four legs or one slightly thinner leg.

To test the performance of these structures over time, they recorded how these structures behaved under repeated compressions using an electron microscope and measured the distance the legs bent.

Polycarpou’s team found that for both defect-free and defective kirigami structures, the compression caused the structures to “stiffen” or resist the downward force. Over time, however, even when compressive forces were extreme, the structures reached a steady-state and were able to recover from the repeated blows from the diamond punch.

The researchers said the results of their cyclic compression experiments suggest that systems with an assembly of kirigami devices can remain functional for a long period of time even if some of the devices within them have defects.

Other contributors to this research include Mohammad Humood from the Texas A&M mechanical engineering department; Jungkyu Lee from Bruker Nano Surfaces; Mengdi Han, Yonggang Huang and John A. Rogers from Northwestern University; Yulin Cui and Yan Shi from Nanjing University of Aeronautics and Astronautics.

Funding for this study was provided by the Hagler Institute for Advanced Study at Texas A&M, where Rogers and Huang are Hagler Faculty Fellows.

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