‘Plug-and-play’ features allow batteries to be wired together for increased power
As our tech needs grow and the Internet of Things increasingly connects our devices and sensors together, figuring out how to provide power in remote locations has become an expanding field of research.
Professor Seokheun “Sean” Choi — a faculty member in the Department of Electrical and Computer Engineering at Binghamton University’s Thomas J. Watson College of Engineering and Applied Science — has been working for years on biobatteries, which generate electricity through bacterial interaction.
One problem he encountered: The batteries had a lifespan limited to a few hours. That could be useful in some scenarios but not for any kind of long-term monitoring in remote locations.
In a new study, published in the Journal of Power Sources and supported by a $510,000 grant from the Office of Naval Research, Choi and his collaborators have developed a “plug-and-play” biobattery that lasts for weeks at a time and can be stacked to improve output voltage and current. Co-authors on the research are from Choi’s Bioelectronics and Microsystems Lab: current PhD student Anwar Elhadad, and Lin Liu, PhD ’20 (now an assistant professor at Seattle Pacific University).
Choi’s previous batteries had two bacteria that interacted to generate the power needed, but this new iteration uses three bacteria in separate vertical chambers: “A photosynthetic bacteria generates organic food that will be used as a nutrient for the other bacterial cells beneath. At the bottom is the electricity-producing bacteria, and the middle bacteria will generate some chemicals to improve the electron transfer.”
The most challenging application for the Internet of Things, Choi believes, will be wireless sensor networks deployed unattended in remote and harsh environments. These sensors will be far from an electric grid and difficult to reach to replace traditional batteries once they run down. Because those networks will allow every corner of the world to be connected, power autonomy is the most critical requirement.
“Right now, we are at 5G, and within the next 10 years I believe it will be 6G,” he said. “With artificial intelligence, we are going to have an enormous number of smart, standalone, always-on devices on extremely small platforms. How do you power these miniaturized devices? The most challenging applications will be the devices deployed in unattended environments. We cannot go there to replace the batteries, so we need miniaturized energy harvesters”
Choi compares these new biobatteries — which measure 3 centimeters by 3 centimeters square — to Lego bricks that can be combined and reconfigured in a variety of ways depending on the electrical output that a sensor or device needs.
Among the improvements he hopes to achieve through further research is creating a package that can float on water and perform self-healing to automatically repair damage incurred in harsh environments.
“My ultimate target is to make it really small,” he said. “We call this ‘smart dust,’ and a couple of bacterial cells can generate power that will be enough to operate it. Then we can sprinkle it around where we need to.”
Original Article: New biobatteries use bacterial interactions to generate power for weeks
More from: Binghamton University
The Latest Updates from Bing News & Google News
Go deeper with Bing News on:
Biobatteries
- High-tech bandages could fend off infections, improve healing
When wounds happen, we want them to heal quickly and without complications, but sometimes infections and other complications prevent it. Chronic wounds are a significant health concern that affects ...
- Self-powered 'bugs' can skim across water to detect environmental data
Researchers at Binghamton University, State University of New York have developed a self-powered "bug" that can skim across the water, and they hope it will revolutionize aquatic robotics.
- Robotics: Self-powered 'bugs' can skim across water to detect environmental data
Researchers have developed a self-powered 'bug' that can skim across the water, and they hope it will revolutionize aquatic robotics.
- How do electric eels work?
However, there are other ways electric eels could inspire us. “We might be able to take electric eel tissue and culture it in a lab to grow biobatteries for storing energy,” suggests Rupert. One team ...
Go deeper with Google Headlines on:
Biobatteries
[google_news title=”” keyword=”biobatteries” num_posts=”5″ blurb_length=”0″ show_thumb=”left”]
Go deeper with Bing News on:
Smart dust
- This $99 smart robot vacuum from Eufy is your key to cleaner floors
Enter the Eufy BoostIQ 30C WiFi Robot Vacuum, the smart cleaning companion that handles the dirty ... This handy robovac is designed to glide effortlessly under furniture, reaching those icky dust ...
- Rollme R3 Smart Ring with titanium body, 5ATM + IP68 water and dust resistance announced
Rollme has launched its latest smart ring, the Rollme R3. This smart ring features a durable titanium alloy exterior and a hypoallergenic epoxy resin lining, making it very light at just around 4 ...
- I lived with two pairs of smart glasses, but only one is worth buying
I've worn the Ray-Ban Meta and Solos AirGo 3 smart glasses, and have learned enough to know which one is worth buying.
- I’ve reviewed smart rings for years. This is the worst one I’ve ever used
The Circular Ring Slim is another smart ring challenger, but is it worth wearing instead of the Oura Ring, which is currently the best you can get?
- The 3 Best Smart Dust Stocks to Buy Now
Investors may want to keep an eye on smart dust stocks. No bigger than a grain of sand, smart dust is made up of tiny microelectromechanical systems (MEMS). All of which can measure and send ...
Go deeper with Google Headlines on:
Smart dust
[google_news title=”” keyword=”smart dust” num_posts=”5″ blurb_length=”0″ show_thumb=”left”]