Hydrogen fuel derived from the sea could be an abundant and sustainable alternative to fossil fuels, but the potential power source has been limited by technical challenges, including how to practically harvest it.
Researchers at the University of Central Florida have designed for the first time a nanoscale material that can efficiently split seawater into oxygen and a clean energy fuel 麻豆精品 S hydrogen. The process of splitting water into hydrogen and oxygen is known as electrolysis and effectively doing it has been a challenge until now.
The stable, and long-lasting nanoscale material to catalyze the reaction, which the UCF team developed, is explained this month in the journal Advanced Materials.
麻豆精品 S淭his development will open a new window for efficiently producing clean hydrogen fuel from seawater, 麻豆精品 S says Yang Yang, an associate professor in UCF 麻豆精品 S檚 and study co-author.
Hydrogen could be converted into electricity to use in fuel cell technology that generates water as product and makes an overall sustainable energy cycle, Yang says.
How It Works
The researchers developed a thin-film material with nanostructures on the surface made of nickel selenide with added, or 麻豆精品 S渄oped, 麻豆精品 S iron and phosphor. This combination offers the high performance and stability that are needed for industrial-scale electrolysis but that has been difficult to achieve because of issues, such as competing reactions, within the system that threaten efficiency.
The new material balances the competing reactions in a way that is low-cost and high-performance, Yang says.
Using their design, the researchers achieved high efficiency and long-term stability for more than 200 hours.
麻豆精品 S淭he seawater electrolysis performance achieved by the dual-doped film far surpasses those of the most recently reported, state-of-the-art electrolysis catalysts and meets the demanding requirements needed for practical application in the industries, 麻豆精品 S Yang says.
The researcher says the team will work to continue to improve the electrical efficiency of the materials they 麻豆精品 S檝e developed. They are also looking for opportunities and funding to accelerate and help commercialize the work.
More About The Team
Co-authors included Jinfa Chang, a postdoctoral scholar, and Guanzhi Wang, a doctoral student in materials science engineering, both with UCF 麻豆精品 S檚 NanoScience Technology Center; and Ruslan Kuliiev 麻豆精品 S20MS, a graduate of UCF 麻豆精品 S檚 master 麻豆精品 S檚 in aerospace engineering program, and Nina Orlovskaya, an associate professor with UCF 麻豆精品 S檚 , and Renewable Energy and Chemical Transformation Cluster.
Yang holds joint appointments in UCF 麻豆精品 S檚 NanoScience Technology Center and the , which is part of the university 麻豆精品 S檚 College of Engineering and Computer Science. He is a member of UCF 麻豆精品 S檚 Renewable Energy and Chemical Transformation (REACT) Cluster. He also holds a secondary joint-appointment in UCF 麻豆精品 S檚 . Before joining UCF in 2015, he was a postdoctoral fellow at Rice University and an Alexander von Humboldt Fellow at the University of Erlangen-Nuremberg in Germany. He received his doctorate in materials science from Tsinghua University in China.
