Researchers Shine a Light on Wearable Technology

Ink jet-printed circuits will be placed between layers of a uniform allowing the LEDs to safely activate if a warfighter suspects an agent threat. (Photo Credit: Shawn Nesaw)

Researchers at the U.S. Army Combat Capabilities Development Command (CCDC) Chemical Biological Center are looking at LEDs to help warfighters battle chemical warfare agents (CWA). Co-primary investigators, Hui Wang, Ph.D. and John Landers, Ph.D. are investigating ways to embed tiny light sources in warfighter uniforms.

Chemical weapons like mustard gas (HD) have been a part of warfighting for over a century. Their use has increased over the last two decades both in warfare and in focused assassinations and attempted assassinations. Enhancing warfighter safety by detecting chemical warfare agents and decontaminating items that come in contact with them is an ever-present focus of the CCDC Chemical Biological Center.

The LEDs work by way of photocatalysis, meaning the light starts the chemical reaction necessary to break down the CWA. "Some chemicals break down under light and some chemicals break down even easier under certain wavelengths of light, let's say a red LED, a green LED and blue LED," Landers explained. "The purpose of the blue LED is to activate a dye that in turn generates a reactive oxygen that breaks down these chemical agents."

Wang and Landers work with boron-dipyrromethene (BODIPY), an organic compound that acts as a photosensitizer, which is a molecule that brings about a chemical change in another molecule (decontamination of the HD molecule in this case) in the presence of light.

"The LED initiates the reaction, activating the dye-like BODIPY and the BODIPY, when exposed to LED light, converts the nearby oxygen to a more reactive form," Wang explained. "It's that reactive oxygen that breaks down the chemical agent. It all begins with the LED."

Because warfighter safety often relies on stealth, Wang and Landers realized that light emitted from LEDs would need obscuration. "Instead of taking an LED and applying it to the surface of clothing, we will incorporate small LEDs with an ink jet-printed circuit between layers of a uniform allowing the LEDs to safely activate if a warfighter suspects an agent threat," Landers said.

Wang and Landers’ solution to masking the light emissions will use conductive silver inks to affix the ink-jet printable circuits and LEDs to one layer of fabric and then cover them with a light-obscuring material.

"Both layers are breathable, and that's one of the main goals of this project - to make a self-decontaminating fabric that's still breathable and reduces the physical burden to the warfighter," Landers said. So, although they will add more layers to warfighters' protective clothing, they won't add significantly more weight.

The two researchers are looking to include metal organic frameworks (MOFs) to their research. "Photosensitizer-containing MOFs will be an alternative to replace the BODIPY dye," Wang said. "The advantage of photosensitizer-containing MOFs is that they not only can adsorb the chemical warfare agent, but also decontaminate them after adsorption."

The MOF fabric will literally add an extra layer of protection, with the nanoparticles working like tiny sponges to absorb the agent before it reaches the warfighter. Next steps will include adding sensors to detect exposure that work in conjunction with the LEDs' and MOFs' abilities to decontaminate.

So far, the project looks more than promising. The LEDs eliminate the need to provide a solution-based decontamination method, so the system is ideal for low-resource environments. Wang and Landers have also found the decontamination process is rapid. Wang says the half-life of the mustard gas (the time it takes for half the chemical to be removed) is under a minute.

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