Researchers from Idaho National Laboratory have developed a new type of electrode for hydrogen production through electrolysis – water splitting. The team has used the electrode to demonstrate efficient hydrogen electrolysis at temperatures far lower than previously possible, which could lead to significant cost reductions in large-scale hydrogen production.
A team at Idaho National Laboratory has created a new type of electrode it says could be used to lower the process costs of large scale hydrogen, potentially allowing the energy to compete with conventional, fossil fuel driven processes used in industry.
In certain areas of hydrogen production, electrolysis can already compete with fossil fuel driven steam reforming, as such processes are difficult to scale down to smaller applications and have high emissions.
The Idaho National Laboratory researchers state: “Although hydrogen is already used to power vehicles, for energy storage and as portable energy, this [their new] approach could offer a more efficient alternative for high-volume production.”
In their paper, the snappily titled 3D self-architectured steam electrode enabled efficient and durable hydrogen production in a proton-conducting solid oxide electrolysis cell at temperatures lower than 600°C – published in the journal Advanced Science – the researchers describe design and production of highly efficient proton conducting solid oxide electrolysis cells (P-SOECs). The cells operated efficiently for more than 75 hours at temperatures lower than, you’ve guessed it, 600°C.
Key to the performance, according to the researchers, was the development of a ceramic steam electrode. “We invented a 3-D self-assembled steam electrode which can be scalable,” says Dr. Dong Ding. “The ultra high porosity and the 3-D structure can make the mass-charge transfer much better, so the performance was better.”
The electrode was created using a woven textile template which is placed in a precursor solution and fired – burning away the textile and leaving behind a ceramic version of the structure. When placed into a solid oxide electrolysis cell, the team observed bridging between the strands in the ceramic textile, which they say should improve performance and stability.
Cells incorporating the new steam electrode were able to perform efficiently at 600°C, and the researchers say there is potential to bring the temperature even lower. Typical SOECs currently operate at temperatures above 800°C, so the new cell could significantly reduce the amount of energy needed to produce hydrogen. The researchers also point out operating at lower temperatures would allow for the removal of several expensive heat resistant materials in the cell design, further reducing costs.
Source PV Magazine