Electric vehicles could be powered by Hydrogen harvested from sewage

  • Hydrogen is valuable as it is a renewable source, and could be sold to the chemicals and plastics industry or used in hydrogen fuel cells for energy storage or electric vehicles
  • The ability to take hydrogen from waste water provides a new economic and environmental opportunity, however until now it has been incredibly expensive to suffice
  • Using a recycled carbon fibre mat, researchers from WMG, University of Warwick, have been able to produce Hydrogen from wastewater for Severn Trent

Wastewater treatment is vital to remove pathogens, but is incredibly energy intensive. The ability to treat it more sustainably is a challenge researchers from WMG, University of Warwick have been able to achieve, using recycled carbon fibre mats to produce hydrogen from waste water.

Treating wastewater is a vital process, as it removes pathogens and protects the environment, however this comes at its own environmental cost, as it is highly energy intensive, using around 3% of energy use in the UK – the equivalent to 13 billion kilowatt hours.

The water and waste company Severn Trent set researchers from WMG, University of Warwick, the challenge of finding a more energy efficient way to treat wastewater, with the team successfully building on research into Microbial Electrolysis Cells.

Microbial Electrolysis Cells involves using electromagnetic microorganisms to break down organic pollutants in waste water, producing clean water and hydrogen gas. The ability to produce Hydrogen gas is valuable in itself as it can be sold to chemical and plastics industry, or for use in hydrogen fuel cells for energy storage or electric vehicles.

Although this all sounds promising it hasn’t been developed on an industrial scale, as the anode materials – which are used in the reaction to breakdown the organic pollutants – are made of graphite or carbon, and cost several hundred pounds per square metre, and produce low rates for Hydrogen.

Dr Stuart Coles and his team therefore took on the challenge of refining the technique by looking at alternative anode materials and processing methods, and successfully identified recycled carbon fibre mats as an alternative anode, which costs only £2 per square metre, making it significantly cheaper than existing anode materials.

After testing the carbon fibre mats on synthetic wastewater and real wastewater, researchers found the bacteria developed on the recycled carbon fibre anode, which had better temperature tolerance and produced more hydrogen than previously used materials.

They then decided to pilot their techniques at Severn Trent’s Minworth waste treatment site, where they successfully processed up to 100 litres of wastewater per day and managed to remove 51% of organic pollutants and up to 100% of suspended solids from the water while producing 18 times more hydrogen (at 100% purity) than the graphite material.

Image of Dr Stuart ColesDr Stuart Coles, from WMG, University of Warwick comments:
“We are really excited about this technology. By taking waste from the automotive and aerospace sectors, we have developed a circular solution to a longstanding problem. Instead of just treating the wastewater, we are now able to extract value from it in the form of hydrogen at a lower cost than ever before.

“The next phase of this work is look at optimising the design of the microbial electrolysis cells and further reduce the level of pollutants in the water. This in turn should help produce even more hydrogen!”

Bob Stear, Chief Engineer at Severn Trent adds:

“The performance boost and cost savings demonstrated from this research mean that MEC technology is one step closer to being cost competitive with existing wastewater treatment assets. WMG have also demonstrated that this technology has the potential to create a more circular wastewater treatment process which will be essential to delivering on our long term sustainability goals and Net Zero plans. We’re currently scoping scaling up the technology at our test-bed plant in Redditch.”

ENDS

2 NOVEMBER 2021

NOTES TO EDITORS

High-res images available at:

https://warwick.ac.uk/services/communications/medialibrary/images/september_2021/img_1054.jpg
Caption: Dr Stuart Coles from WMG, University of Warwick with graphene
Credit: WMG, University of Warwick

https://warwick.ac.uk/services/communications/medialibrary/images/september_2021/img_1054.jpg
Caption: Dr Stuart Coles from WMG, University of Warwick with graphene
Credit: WMG, University of Warwick

https://warwick.ac.uk/services/communications/medialibrary/images/september_2021/img_1043.jpg
Caption: Dr Stuart Coles from WMG, University of Warwick with graphene
Credit: WMG, University of Warwick

https://warwick.ac.uk/services/communications/medialibrary/images/september_2021/img_1058.jpg
Caption: A sample of a roll of graphene
Credit: WMG, University of Warwick

For further information please contact:

Alice Scott
Media Relations Manager – Science
University of Warwick
Tel: +44 (0) 7920 531 221
E-mail: alice.j.scott@warwick.ac.uk

Source:WMG News Item (warwick.ac.uk)