Tag: Organic electronics

Wearable tech that’s safe for the body and kind to the environment

Wearable tech that’s safe for the body and kind to the environment

The world of wearable technology – such as sensors and energy-producing devices – is expanding, thanks to new research into a unique combination of materials that are flexible, safe to use on or inside the human body, and environmentally friendly.

Dr. Simon Rondeau-Gagné, along with a team of collaborators and graduate students, used the Canadian Light Source (CLS) at the University of Saskatchewan to show that semiconducting polymers and collagen – the main component of human skin – can be combined to create organic devices “that are more efficient, more conformable and specifically…more green as well.”

Collagen provided both the skin-like rigidity and elasticity (or bendability) the researchers were looking for in “a platform that can be integrated with something like the human body,” said Rondeau-Gagné, an associate professor in the Department of Chemistry and Biochemistry at the University of Windsor. Incorporating a polyester polymer gave the devices weeks-long stability but also eventual biodegradability. The research results were recently published in the journal ACS Applied Materials & Interfaces.

“We want our devices to be stable enough that they can be used, but unstable enough to not end up accumulating and not creating any kind of problems in the environment, such as microplastic pollution,” he said. “We’re concerned about the environmental footprint and what happens when you dispose of these future technologies.”

Rondeau-Gagné says that, now that they shown their materials are flexible and match the performance of devices made from non-biodegradable components, the sky’s the limit in term of possible applications for organic electronics. In the short term, such a device could be attached to plants to measure, for example, leaf growth. “As the leaf grows, the stretchable device could measure that and provide data about various growing conditions in a greenhouse or in the field.”

This research is part of the Agriculture UWindsor Centre of Excellence (AGUWin), an initiative dedicated to advancing agricultural research, skills training, and sustainable practices.

Read more on CLS website

From cannabis harvest to flexible solar panels

From cannabis harvest to flexible solar panels

University of Ottawa researchers using CLS to develop next-gen electronic devices

Organic electronics – electronics where the active material is carbon-based – are making possible diverse new technologies ranging from sensors for monitoring cannabinoid levels in cannabis plants to lightweight, bendable solar panels. Real world applications would mean solar panels you roll up and take with you on your next camping trip, or cannabis producers knowing the optimal time to harvest plants.

Key to these advances is a class of substances called conductive polymers, which have good optical and mechanical properties but are cheaper to manufacture than conventional electronics, thanks to low energy requirements; they can be printed in long, thin sheets – like a newspaper – but don’t require the same high temperatures (> 1000° Celsius). Researchers from the University of Ottawa recently used the Canadian Light Source at the University of Saskatchewan to study how different manufacturing processes can affect the performance of the resulting electronic devices.

“While these applications all sound really different, the reality they all have similar structures and need to be manufactured in similar ways,” explained Benoit Lessard, University of Ottawa professor and Canada Research Chair in the Department of Chemical and Biological Engineering.

Using the Brockhouse beamline at the CLS, Lessard and his team have been able to examine – at a microscopic level – how the carbon molecules behave during manufacturing. What they’re learning will have huge implications on how cutting-edge devices are manufactured, their size, flexibility, and electronic functionality. Their results are published in the journal ACS Applied Materials & Interfaces.

Read more on Canadian Light Source website

Credit:  Mobile Solar Power, CC BY-SA 4.0 <https://creativecommons.org/licenses/by-sa/4.0>, via Wikimedia Commons