Additive manufacturing: A new twist for stretchable electronics?

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On January 3, 2017

New bendable, foldable, twistable electronic devices like the one pictured above could become more common in the future. Photo by John Rogers, University of Illinois, courtesy of the National Science Foundation.

New bendable, foldable, twistable electronic devices like the one pictured above could become more common in the future. Photo by John Rogers, University of Illinois, courtesy of the National Science Foundation.

New bendable electronic devices like the one pictured above could become more common in the future. Photo by John Rogers, University of Illinois, courtesy of the National Science Foundation.

Electronic components that can be elongated or twisted – known as “stretchable” electronics – could soon be used to power electronic gadgets, the onboard systems of vehicles, medical devices and other products. And a 3-D printing-like approach to manufacturing may help make stretchable electronics more prevalent, say researchers at Missouri University of Science and Technology.

Writing in the January 2017 edition of the journal Micromachines, Missouri S&T researchers assess the current state of the emerging field of stretchable electronics, focusing on a type of conductor that can be built on or set into the surface of a polymer known as elastomer.

These conductors could one day replace the rigid, brittle circuit board that powers many of today’s electronic devices. They could be used, for example, as wearable sensors that adhere to the skin to monitor heart rate or brain activity, as sensors in clothing or as thin solar panels that could be plastered onto curved surfaces.

Dr. Heng Pan working in his lab with graduate student Brandon Ludwig. Sam O'Keefe/Missouri S&T

Dr. Heng Pan working in his lab with graduate student Brandon Ludwig. Sam O’Keefe/Missouri S&T

Key to the future of stretchable electronics is the surface, or substrate. Elastomer, as its name implies, is a flexible material with high elasticity, which means that it can be bent, stretched, buckled and twisted repeatedly with little impact on its performance.

One challenge facing this class of stretchable electronics involves “overcoming mismatches” between the flexible elastomer base and more brittle electronic conductors, the researchers explain in their paper, “Materials, Mechanics, and Patterning Techniques for Elastomer-Based Stretchable Conductors” (Micromachines 2017, 8(1), 7).

“Unique designs and stretching mechanics have been proposed to harmonize the mismatches and integrate materials with widely different properties as one unique system,” writes the research team, which is led by Dr. Heng Pan, assistant professor of mechanical and aerospace engineering at Missouri S&T.

A relatively new manufacturing technique known as additive manufacturing may help resolve this issue, Pan says.

Additive manufacturing is a process that allows manufacturers to create three-dimensional objects, layer by layer – much like 3-D printing, but with metals, ceramics or other materials. In their paper, the researchers suggest that additive manufacturing could be used to “print” very thin layers of highly conductive materials onto an elastomer surface.

“With the development of additive manufacturing, direct writing techniques are showing up as an alternative to the traditional subtractive patterning methods,” the S&T researchers say.

Subtractive approaches include photolithography, which is commonly used to manufacture semiconductors.

Pan and his colleagues see additive manufacturing as a relatively economical approach to creating these new devices. At Missouri S&T, they are testing an approach that Pan calls “direct aerosol printing.” The process involves spraying a conductive material and integrating with a stretchable substrate to develop sensors that can be placed on skin.

“With the increase of complexity and resolution of devices, higher requirements for patterning techniques are expected,” they write. “Direct printing, as an additive manufacturing method, would satisfy such requirements and offer low cost and high speed in both prototyping and manufacturing. It might be a solution for cost-effective and scalable fabrication of stretchable electronics.”

Yet further challenges must be addressed before stretchable electronics become widely used as components in consumer electronics, medical devices or other fields, the researchers say. These challenges include the development of stretchable batteries that can store energy and the need to ensure that stretchable electronics and the malleable surfaces they’re built upon perform and age well together.

Nevertheless, Pan and his colleagues are optimistic for the future of stretchable electronics. They foresee a growth in the types of materials that could be used as efficient conductors of electricity and as flexible surfaces on which to build stretchable electronics.

Pan’s co-authors of the Micromachines paper are Xiaowei Yu and Wan Shou, both Ph.D. students in mechanical engineering at Missouri S&T, and Bikram K. Mahajan, a master’s student in mechanical engineering at Missouri S&T. Their paper was first published online Dec. 27, 2016.

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