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Researchers develop a cost-effective, efficient rival for platinum

By R&D Editors | February 18, 2015

This image shows single shell carbon-encapsulated iron nanoparticles. Image: Aalto Univ.Researchers succeeded in creating an electrocatalyst that is needed for storing electric energy made of carbon and iron.

A challenge that comes with the increased use of renewable energy is how to store electric energy.

Platinum has traditionally been used as the electrocatalyst in electrolyzers that store electric energy as chemical compounds. However, platinum is a rare and expensive metal. Now Aalto Univ. researchers have succeeded in developing a substitute to it that is cheap and effective.

“We developed an electrocatalyst that is made of iron and carbon. Now the same efficiency that was achieved with platinum can be obtained with a less expensive material. Nearly 40% of the material costs of energy storage with an electrolyzer come from the electrocatalyst,” says senior scientist Tanja Kallio.

The findings have been published in Angewandte Chemie.

Losses decrease
The manufacturing process has been developed in cooperation with a research group led by Prof. Esko Kauppinen from Aalto Univ. School of Science. The carbon nanotube the group developed conducts electricity extremely well and serves as the support, while the now added only single carbon layer covered iron functions as the catalyst. The manufacturing process has a single stage.

In the manufacturing phase, the iron is covered with graphene.

“The method has been altered to make the electro catalyst very active. By active, we refer to the small amount of energy needed to store electric energy as hydrogen. This reduces the losses caused by chemical storage and the process is economically viable.”

Source: Aalto Univ.

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