Dan’s Biz Bookshelf: ‘Born to Create’
It’s Only Common Sense: Invest in Yourself—You’re Your Most Important Resource
Marcy's Musings: Engineering Economics
Cotton Candy Capillaries Lead to PCBs That Dissolve When Cooled
June 28, 2017 | Vanderbilt UniversityEstimated reading time: 2 minutes
Building transient electronics is usually about doing something to make them stop working: blast them with light, soak them with acid, dunk them in water.
Professor Leon Bellan’s idea is to dissolve them with neglect: Stop applying heat, and they come apart.
Using silver nanowires embedded in a polymer that dissolves in water below 32 degrees Celsius — between body and room temperature — Bellan and mechanical engineering graduate student Xin Zhang made a simple circuit board that, so far, just turns on an LED light. Its potential applications are far more promising.
“Let’s say you use this technology to make an RFID wireless tag,” said Bellan, assistant professor of mechanical and biomedical engineering at Vanderbilt University. “You could implant important information in a person, and body temperature would keep it intact. If the tag were removed or the bearer died, it would dissolve. You could use it for implanted medical devices as well – to cause them to disintegrate, it would only require applying ice to the skin.”
In the lab, his tiny circuit boards stay operational in water warmed by a hot plate. Turn off the hot plate, and they start dissolving in minutes.
The duo’s paper, available online and soon to be published in the journal ACS Applied Materials and Resources, represents an application of technology Bellan developed last year. Using a special polymer and a cotton candy machine purchased from a department store, he spun networks of threads comparable in size, density and complexity to capillaries – the tiny conduits that deliver oxygen and nutrients to cells.
Bellan’s cotton candy-like fiber networks can be embedded in materials that mimic the extracellular matrix and then be triggered to dissolve away, potentially producing capillary systems for artificial organs. He’s using the same triggering system to produce transient electronics.
In this system, the silver nanowires are held together in the polymer so that they touch, and as long as the polymer doesn’t dissolve, the nanowires will form a path to conduct electricity similar to the traces on a circuit board. Trigger the polymer to dissolve by lowering the temperature, and the nanowire network disintegrates, destroying the conductive path.
“Transient electronics are cool, and once you start coupling that to a stimulus-responsive material, you start coming up with really sci-fi ideas,” Bellan said. “You could have any cascade of events that results in a very unique stimulus that causes it to degrade or prevent it from falling apart. Temperature is just the beginning.”
The next steps are integrating semiconductors to make transistors and ensuring users can interact wirelessly with the device.
Related video:
Original by: Heidi Hall
Share on:
Suggested Items
Siemens Unveils Next Generation AI-enhanced Electronic Systems Design Software
11/13/2024 | SiemensSiemens Digital Industries Software announced today the latest advancement in its electronic systems design portfolio. The next generation release takes an integrated and multidisciplinary approach, bringing together Xpedition™ software, HyperLynx software and PADS Professional software into a unified user experience that delivers cloud connectivity and AI capabilities to push the boundaries of innovation in electronic systems design.
Happy’s Tech Talk #34: Producibility and Other Pseudo-metrics
11/12/2024 | Happy Holden -- Column: Happy’s Tech TalkAs an engineer, I thrive on data, and one of my favorite forms is metrics. However, the one metric that has always challenged me is producibility. I define this as more than just passing a DRC in CAM, but the entire envelope of “simplicity of design,” “suitability for test,” and many more. Yet, producibility seemed to be different for different engineers and we had no clear way to establish and define producibility other than opinion. When I worked at HP, the company invested in a methodology called design for manufacturing and assembly using the GE/Hitachi Methodology and Dewhurst-Boothroyd software. Finally, I had a methodology that created a producibility score.
The Quest for Perfect Products
11/11/2024 | Marcy LaRont, I-Connect007Anna-Katrina Shedletsky is a former Apple engineer who formed her own company, Instrumental, to address what she felt were frustrating and costly engineering problems and inefficiencies at Apple. She’s passionate about her quest to build perfect products faster than ever before. In this interview, Anna shares her journey from creating innovative products like the Apple Watch to addressing the complexities of failure analysis in manufacturing. She also discusses an upcoming educational webinar she is hosting with Valentina Ratner, CEO of AllSpice.io, for engineering leaders in the manufacturing space. They look forward to providing “real talk” and value to their engineering colleagues.
Cicor Expands into Sweden with Plans to Strengthen Market Position in Germany
11/08/2024 | CicorCicor Group has acquired the Swedish development company Nordic Engineering Partner AB and thus establishes a significant presence in the Nordics. Additionally, Cicor is in advanced negotiations to acquire another German EMS provider.
Root-cause Analysis and Problem-solving
11/01/2024 | Happy Holden, I-Connect007An essential skill for any process engineer in printed circuit fabrication is the ability to conduct root-cause analysis (RCA) and problem-solving. These are related to TQC and Six Sigma applications and are essential for customer support and continued profitability. All engineers will encounter these methods sooner or later, but it will likely be sooner if you are in product or process engineering in manufacturing.