Zinc-air batteries, which produce electricity through a chemical reaction between oxygen in the atmosphere and zinc, are considered to be next-generation candidates to meet the explosive demand for electric vehicles instead of lithium-ion batteries. They theoretically meet all required characteristics for next-generation secondary batteries, such as; high energy density, low risk of explosion, eco-friendliness that does not emit pollutants, and low cost of materials (zinc and air, which can be easily obtained from nature).
The Korea Institute of Science and Technology (KIST, President Seok-Jin Yoon) announced that its research team led by Dr. Joong Kee Lee (Energy Storage Research Center) developed a technology to improve the electrochemical performance of zinc-air batteries by utilizing solar energy, which is emerging as a new research and development area in the secondary battery field.
The battery developed by the research team utilizes a photoactive bifunctional air-electrocatalyst with a semiconductor structure with alternating energy levels, which significantly improves the rates of oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) that generate electricity. The photoactive bifunctional catalyst is a compound that accelerates chemical reactions by absorbing light energy and has a improved light absorption ability than conventional zinc-air battery catalysts.
In a zinc-air battery that uses metal and air as the anode and cathode of the battery, OER and ORR must be alternately performed for electrical energy conversion of oxygen as the cathode active material. Therefore, the catalytic activity of the positive electrode current collector, made of carbon material, is an important factor in determining the energy density and overall cell efficiency of zinc-air batteries.
Accordingly, the KIST research team focused on the p-n heterojunction, the basic structural unit of solar cells and semiconductors, as a measure to improve the slow catalytic activity of zinc-air batteries. The goal was to accelerate the oxygen production-reduction process by using the interface characteristics of semiconductors in which electron movement occurs. To this end, a cathode material with a heterojunction bandgap structure was synthesized, with a n-type semiconductor (graphitic carbon nitride, g-C3N4)andap-typesemiconductor(copper-doppedZIF-67(ZeoliticImidazolateFramework-67),CuZIF-67).
In addition, an experiment was conducted under real-world conditions without light in order to confirm the commercial potential of the photoactive bifunctional catalyst with a p-n heterojunction structure with alternating energy levels. The prototype battery showed an energy density of 731.9 mAh gZn-1, similar to the best performance of the existing zinc-air battery. In the presence of sunlight, the energy density increased by about 7% up to 781.7 mAh gZn-1and excellent cycle performance (334 hours, 1,000 cycles), exhibiting the best performance among known catalysts.
Dr. Lee said, “Utilization of solar energy is an important part not only in improving the electrochemical performance of secondary batteries but also in realizing a sustainable society. We hope that this technology will become a catalyst that stimulates the development of new convergence technologies in semiconductor physics and electrochemistry, in addition to solving the difficulties of metal-air batteries that are emerging as an alternative to lithium-ion batteries.”
We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain.
With the rise of Ad Blockers, and Facebook – our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don’t have a paywall – with those annoying usernames and passwords.
Our news coverage takes time and effort to publish 365 days a year.
If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
$5 Billed Once
credit card or paypal
SpaceDaily Monthly Supporter
$5 Billed Monthly
Solar power down
Paris (ESA) Apr 04, 2022
Solar energy generation keeps on becoming cheaper and more efficient, but some basic limitations will always apply: solar panels can only generate power during the daytime, and much of the sunlight is absorbed by the atmosphere as it shines downward.
So ESA is working on the concept of collecting solar power up in orbit, where sunlight is up to 11 times more intense than across European territory, then beaming it down to the ground for use.
As part of that effort, a new project looks into de … read more