MIT engineers fabricated a chip-free, wireless electronic ‘skin’. The device senses and wirelessly transmits signals related to pulse, sweat and ultraviolet exposure, without bulky chips or batteries. Image courtesy of the researchers.
MIT engineers fabricated a chip-free, wireless electronic ‘skin’. The device senses and wirelessly transmits signals related to pulse, sweat and ultraviolet exposure, without bulky chips or batteries. Image courtesy of the researchers.

Wearable sensors are ubiquitous thanks to wireless technology that allows a person’s glucose concentrations, blood pressure, heart rate and activity levels to be transmitted seamlessly from sensor to smartphone for further analysis.

Today, most wireless sensors communicate via embedded Bluetooth chips that are themselves powered by small batteries. But these conventional chips and power sources will likely be too bulky for next-generation sensors, which are taking on smaller, thinner, more flexible forms.

Now engineers at Massachusetts Institute of Technology (MIT) have devised a new kind of wearable sensor that communicates wirelessly without requiring onboard chips or batteries. Their design, detailed in a paper in Science, opens a path toward chip-free wireless sensors.

The team’s sensor design is a form of electronic skin, or ‘e-skin’ – a flexible, semiconducting film that conforms to the skin like electronic Scotch tape. The heart of the sensor is an ultrathin, high-quality film of gallium nitride, a material that is known for its piezoelectric properties, meaning it can both produce an electrical signal in response to mechanical strain and mechanically vibrate in response to an electrical impulse.

The researchers found they could harness gallium nitride’s two-way piezoelectric properties and use the material simultaneously for both sensing and wireless communication.

In their new study, the team produced pure, single-crystalline samples of gallium nitride, which they paired with a conducting layer of gold to boost any incoming or outgoing electrical signal. They showed that this device was sensitive enough to vibrate in response to a person’s heartbeat, and even the salt in their sweat, and that the material’s vibrations generated an electrical signal that could be read by a nearby receiver. In this way, the device was able to wirelessly transmit sensing information, without the need for a chip or battery.

“Chips require a lot of power, but our device could make a system very light without having any chips that are power-hungry,” says Jeehwan Kim, an associate professor of mechanical engineering and of materials science and engineering at MIT and the paper’s corresponding author.

“You could put it on your body like a bandage, and paired with a wireless reader on your cellphone, you could wirelessly monitor your pulse, sweat and other biological signals.”

Kim’s group previously developed a technique called remote epitaxy that they employed to quickly grow and peel away ultrathin, high-quality semiconductors from wafers coated with graphene. Using this technique, they have fabricated and explored various flexible, multifunctional electronic films.

In their new study, the engineers used the same technique to peel away ultrathin, single-crystalline films of gallium nitride, which in its pure, defect-free form is a highly sensitive piezoelectric material.

The team looked to use a pure film of gallium nitride as both a sensor and a wireless communicator of surface acoustic waves, which are essentially vibrations across the films. The patterns of these waves can indicate a person’s heart rate – or even more subtly, the presence of certain compounds on the skin, such as salt in sweat.

The researchers hypothesized that a gallium nitride-based sensor, adhered to the skin, would have its own inherent, ‘resonant’ vibration or frequency that the piezoelectric material would simultaneously convert into an electrical signal, the frequency of which a wireless receiver could register. Any change to the skin’s conditions, such as from an accelerated heart rate, would affect the sensor’s mechanical vibrations, and the electrical signal that it automatically transmits to the receiver.

“If there is any change in the pulse, or chemicals in sweat, or even ultraviolet exposure to skin, all of this activity can change the pattern of surface acoustic waves on the gallium nitride film,” notes Yeongin Kim, first author and former MIT postdoc, who is now an assistant professor at the University of Cincinnati. “And the sensitivity of our film is so high that it can detect these changes.”

To test their idea, the researchers produced a thin film of pure, high-quality gallium nitride and paired it with a layer of gold to boost the electrical signal. They deposited the gold in the pattern of repeating dumbbells – a lattice-like configuration that imparted some flexibility to the normally rigid metal. The gallium nitride and gold, which the researchers consider to be a sample of electronic skin, measures just 250nm thick.

They placed the new e-skin on volunteers’ wrists and necks, and used a simple antenna, held nearby, to wirelessly register the device’s frequency without physically contacting the sensor itself. The device was able to sense and wirelessly transmit changes in the surface acoustic waves of the gallium nitride on volunteers’ skin related to their heart rate.

The team also paired the device with a thin ion-sensing membrane, which can selectively attract a target ion – in this case, sodium. With this enhancement, the device could sense and wireless transmit changing sodium levels as a volunteer held onto a heat pad and began to sweat.

The researchers see their results as a first step toward chip-free wireless sensors, and they envision that the current device could be paired with other selective membranes to monitor other vital biomarkers.

“We showed sodium sensing, but if you change the sensing membrane, you could detect any target biomarker, such as glucose, or cortisol related to stress levels,” says co-author and MIT postdoc Jun Min Suh. “It’s quite a versatile platform.”

This story is adapted from material from MIT, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.

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