Share this article:
The Next Wearable Technology Could Be Your Skin
Technology can be awkward. Our pockets are weighed down with ever-larger smartphones that are a pain to pull out when we’re in a rush. And attempts to make our devices more easily accessible with smart watches have so far fallen flat. But what if a part of your body could become your computer, with a screen on your arm and maybe even a direct link to your brain?
Artificial electronic skin (e-skin) could one day make this a possibility. Researchers are developing flexible, bendable and even stretchable electronic circuits that can be applied directly to the skin. As well as turning your skin into a touchscreen, this could also help replace feeling if you’ve suffered burns or problems with your nervous system.
The simplest version of this technology is essentially an electronic tattoo. In 2004, researchers in the US and Japan unveiled a pressure sensor circuit made from pre-stretched thinned silicon strips that could be applied to the forearm. But inorganic materials such as silicon are rigid and the skin is flexible and stretchy. So researchers are now looking to electronic circuits made from organic materials (usually special plastics or forms of carbon such as graphene that conduct electricity) as the basis of e-skin.
Typical e-skin consists of a matrix of different electronic components – flexible transistors, organic LEDs, sensors and organic photovoltaic (solar) cells – connected to each other by stretchable or flexible conductive wires. These devices are often built up from very thin layers of material that are sprayed or evaporated onto a flexible base, producing a large (up to tens of cm2) electronic circuit in a skin-like form.
Much of the effort to create this technology in the last few years has been driven by robotics and a desire to give machines human-like sensing capabilities. We now have e-skin devices that can detect approaching objects and measure temperature and applied pressure. These can help robots work more safely by being more aware of their surroundings (and any humans that might get in the way). But if integrated with wearable technology, they could do the same for humans, detecting, for example, harmful movements during sport.
But will we one day come to build this technology directly into our bodies, and how common will it be? The problem with organic electronics at the moment is that they aren’t very reliable and give relatively poor electronic performance. Just like real skin, the e-skin developed so far eventually develops wrinkles. These cause its layers to come apart and the circuits to fail. Plus, atoms in organic materials are more chaotically organised than the inorganic materials used to make traditional electronics. This means electrons move 1,000 times slower in organic materials, so devices made from them will operate much more slowly and would’t deal as well with the heat the circuits generate.
The other big issue is how to integrate e-skin with the human body so that it doesn’t cause medical problems and so that it can interface with the nervous system. Organic materials are carbon-based (like our bodies) so in some senses are more likely to be biocompatible and not rejected by the body. But carbon particles are good at passing through the cells that make up our body and this would likely to lead to inflammation, generating an immune response that could even, according to certain unverified theories, generate tumours.
However, scientists have already had some success linking electronic devices to the nervous system. Researchers at the University of Osaka are leading pioneering research to develop a brain implant from a flexible matrix of organic thin-film transistors that could be activated just by thinking. The difficulty is that such an invasive approach could lead to further problems, especially when we start testing the technology on humans.
In coming years we are are likely to see prototype e-skin devices gaining momentum in the form of wearable bodily sensors, and potentially as a way to harvest energy from the body’s movement. What will take much longer are the more complicated circuits such as those found in smartphones. And the other big question we’ve yet to answer is how many people will accept permanent or semi-permanent electronic implants. Would you be willing to effectively become a cyborg?
This article was originally published in The Conversation under a Creative Commons Attribution No Derivatives license. Read the original article here.
Chapters in the first section of the book summarise recent developments in electrically conductive fabric structures and puts together a few theoretical treatments of the electro-mechanical properties of various fabric structures. The next section reviews topics related to wearable photonics such as fibre optic sensors and integrated smart textile structures, the developments in various flexible photonic display technologies as well as looking at current communication apparel and optical fibre fabric displays. Next the book focuses on integrated structures and system architectures. Finally the issues facing a fashion designer working with wearables are explored.
Wearable electronics and photonics covers many aspects of the cutting-edge research and development into this exciting field and provides a window through which only a small portion of the exciting emerging technology can be seen. With contributions from a panel of international experts in the field this is an essential guide for all electrical, textile and biomedical engineers as well as academics and fashion designers.
Save up to 30% on your own copy when you purchase via the Elsevier store. Enter code STC215 at the checkout!
Engineering brings science and technology out of the lab and into the real world. Often without thinking about it, we engage every day with technology that is the product of careful, precise design and execution by engineers in electronics, optics, and communications; embedded systems; automotive, aerospace, and marine; mechanical; and many other disciplines. For decades, Elsevier has maintained and grown extensive collections in these and other cutting-edge areas, like biomechanics and nanotechnology, through our trusted imprints: Newnes, Academic Press, and Woodhead Publishing. In addition, our powerful online platforms like Knovel and Engineering Village help streamline research and development processes for users around the world.