Seeing the light: Researchers offer solution for efficiency problem of artificial photosynthesis

December 05, 2018

Hydrogen-powered electronics, travel, and more may be a step closer thanks to the work of a collaborative team of scientists in Japan. The researchers have developed a new method to more efficiently produce a key component needed to convert solar energy and water into hydrogen fuel, a process called photoelectrochemical water splitting.

They published their results in October in Applied Energy Materials, a journal of the American Chemical Society.

"With the abundance of solar energy and water, photoelectrochemical water splitting is a promising way to ease global environment and energy-storage issues," said lead author Katsuya Teshima, a professor of the Department of Materials Chemistry and the director of the Center for Energy and Environmental Science at Shinshu University. Teshima is also affiliated with the Nagano Prefecture Nanshin Institute of Technology.

In water splitting, a photo anode, which is a semiconductor and a metal cathode, absorbs sunlight. The semiconductor absorbs high-energy photons from that light, which forces splitting of the molecules around the semiconductor. This causes oxygen to divorce from hydrogen and combine with other free oxygen molecules. Hydrogen pairs and oxygen pairs can then be separately funneled through to the appropriate cathodes to be stored and used as energy.

The problem, however, according to Teshima and coworker, Suzuki, is that the first proposed photo anodes could only absorb UV light, which accounts for about five percent of the solar spectrum. Made of titanium oxide, these photo anodes are highly efficient at converting the solar energy they do capture, but they're not a viable option for industrial use because they capture so little solar energy.

Teshima and his team have turned to tantalum nitride, one of the most promising light-responsive materials available for use in water splitting. Not only can it absorb visible light, but it can also absorb light with a wavelength up to 600 nanometers, which allows for even more light absorption. The researchers previously fabricated the tantalum nitride crystals, but the process was complicated and the resulting crystal layer varied in thickness and coverage. Such unevenness can lead to inefficient or even completely ineffective water splitting efforts.

In this new attempt, Teshima placed the metal tantalum samples on top of powder sodium compounds, and heated them with ammonia gas at high temperatures. The researchers could control how evenly the sodium compounds reacted with the tantalum, as well as how thick the crystal layer grew by altering the ratio of the sodium compounds, the temperature, and the time.

"Our ultimate goal is to efficiently produce hydrogen and oxygen gasses from natural water by use of our flux-grown photo anode," Teshima said. "As environment and energy problems are global issues, we want to contribute to their solutions."
-end-
The other authors on this paper are Sayaka Suzuki, Minori Yanai, Hajime Wagata, all of whom are affiliated with the Department of Materials Chemistry, Faculty of Engineering at Shinshu University; Tetsuya Yamada of the Center for Energy and Environmental Science at Shinshu University; Yutaka Sasaki of the School of Engineering at the University of Tokyo; Shuji Oishi, with affiliations at both the Department of Materials Chemistry, Faculty of Engineering and the Center for Energy and Environmental Science at Shinshu University; and Kazunari Domen, who is affiliated with both the Center for Energy and Environmental Science at Shinshu University and the School of Engineering at the University of Tokyo. This work was supported by Grants-in-Aid for Scientific Research, Grants-in-Aid for Young Scientists, and the Japan Technological Research Association of Artificial Photosynthetic Chemical Process.

About Shinshu University

Shinshu University is a national university in Japan founded in 1949 and working on providing solutions for building a sustainable society through interdisciplinary research fields: material science (carbon, fiber, composites), biomedical science (for intractable diseases, preventive medicine), and mountain science. We aim to boost research and innovation capability through collaborative projects with distinguished researchers from the world. For more information, please see: http://www.shinshu-u.ac.jp/english/

Shinshu University

Related Hydrogen Articles from Brightsurf:

Solar hydrogen: let's consider the stability of photoelectrodes
As part of an international collaboration, a team at the HZB has examined the corrosion processes of high-quality BiVO4 photoelectrodes using different state-of-the-art characterisation methods.

Hydrogen vehicles might soon become the global norm
Roughly one billion cars and trucks zoom about the world's roadways.

Hydrogen economy with mass production of high-purity hydrogen from ammonia
The Korea Institute of Science and Technology (KIST) has made an announcement about the technology to extract high-purity hydrogen from ammonia and generate electric power in conjunction with a fuel cell developed by a team led by Young Suk Jo and Chang Won Yoon from the Center for Hydrogen and Fuel Cell Research.

Superconductivity: It's hydrogen's fault
Last summer, it was discovered that there are promising superconductors in a special class of materials, the so-called nickelates.

Hydrogen energy at the root of life
A team of international researchers in Germany, France and Japan is making progress on answering the question of the origin of life.

Hydrogen alarm for remote hydrogen leak detection
Tomsk Polytechnic University jointly with the University of Chemistry and Technology of Prague proposed new sensors based on widely available optical fiber to ensure accurate detection of hydrogen molecules in the air.

Preparing for the hydrogen economy
In a world first, University of Sydney researchers have found evidence of how hydrogen causes embrittlement of steels.

Hydrogen boride nanosheets: A promising material for hydrogen carrier
Researchers at Tokyo Institute of Technology, University of Tsukuba, and colleagues in Japan report a promising hydrogen carrier in the form of hydrogen boride nanosheets.

World's fastest hydrogen sensor could pave the way for clean hydrogen energy
Hydrogen is a clean and renewable energy carrier that can power vehicles, with water as the only emission.

Chemical hydrogen storage system
Hydrogen is a highly attractive, but also highly explosive energy carrier, which requires safe, lightweight and cheap storage as well as transportation systems.

Read More: Hydrogen News and Hydrogen Current Events
Brightsurf.com is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to Amazon.com.