Hydrogen economy on the cards thanks to new method

Hydrogen as a fuel is a dream that we have all been waiting to get fulfilled and while we have achieved a level of efficiency and cost reduction, more studies continue towards making hydrogen economy a reality.

One such study by Washington State University researchers has led to finding of a more efficient method to generate hydrogen from water – an important key to making clean energy more viable. Using inexpensive nickel and iron, the researchers developed a very simple, five-minute method to create large amounts of a high-quality catalyst required for the chemical reaction to split water. Findings of the study have been published in journal Nano Energy.

Energy conversion and storage is a key to the clean energy economy. Because solar and wind sources produce power only intermittently, there is a critical need for ways to store and save the electricity they create. One of the most promising ideas for storing renewable energy is to use the excess electricity generated from renewables to split water into oxygen and hydrogen. Hydrogen has myriad uses in industry and could be used to power hydrogen fuel-cell cars.

Industries have not widely used the water splitting process, however, because of the prohibitive cost of the precious metal catalysts that are required – usually platinum or ruthenium. Many of the methods to split water also require too much energy, or the required catalyst materials break down too quickly.

In their work, the researchers, led by professor Yuehe Lin in the School of Mechanical and Materials Engineering, used two abundantly available and cheap metals to create a porous nanofoam that worked better than most catalysts that currently are used, including those made from the precious metals. The catalyst they created looks like a tiny sponge. With its unique atomic structure and many exposed surfaces throughout the material, the nanofoam can catalyze the important reaction with less energy than other catalysts. The catalyst showed very little loss in activity in a 12-hour stability test.

 

The researchers are now seeking additional support to scale up their work for large-scale testing.

Marjory Lewis

About Marjory Lewis

Marjory has a degree in Chemistry has been an active journalist covering the pharmaceutical industry. She is well versed with scientific terminologies as well as the business aspects of the industry.

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