Graphene to reduce cost of heavy water production in the nuclear industry by 100 times

Graphene could help reduce the energy cost of producing heavy water and decontamination in nuclear power plants by over one hundred times compared with current technologies, according to a new study.

The new development could lead to the reduction of CO2 emissions associated with heavy water production by up to a million tonnes each year.

A team from the University of Manchester led by Dr Marcelo Lozada-Hidalgo demonstrated fully scalable prototypes of graphene membranes capable of producing heavy water.

Heavy water is used by the nuclear industry as a key part of the reaction process to create energy but it is expensive to produce.

Graphene-based membranes could make the production of heavy water more efficient through its ability to effectively isotopically separate particles, leading to greener and cheaper nuclear power.

Separating hydrogen isotopes is a huge task for nuclear fission and future fusion plants. Thousands of tons of isotopic mixtures are processed every year. Yet, producing just 1 kg of heavy water consumes enough energy to power an average American household for an entire year.

“This is a crucial milestone in the path to taking this revolutionary technology to industrial application,” Lozada-Hidalgo said.

“The potential gains are high enough to justify its introduction even in the highly conservative nuclear industry.”

Only last year, the same group of researchers found that graphene can efficiently sieve hydrogen isotopes. But the industrial opportunities of this discovery were not analysed because there were no membranes or fabrication methods suitable for scalable manufacturing at the time.

The research team has developed fully scalable prototype membranes and demonstrated the isotope separation in pilot scale studies.

They found that the high efficiency of the separation would allow for a significant reduction of the input amount of raw isotope mixtures that needs to be processed. This reduces both the capital costs and the energy requirements.

They estimated over one hundred times less energy to produce heavy water would be required compared to competing technologies – even larger energy savings are anticipated for tritium decontamination.

Sheng Zhang, University of Manchester research fellow said: “This is a crucial milestone in the path to taking this revolutionary technology from our lab to the industry.

“The potential gains are high enough to justify its introduction even in the highly conservative nuclear industry.”

Manchester professor Sir Andre Geim, added: “Tritium discharged both from nuclear power plants and as a result of environmental disasters is a major global concern.

“We believe this technology can economically transform the environmental footprint of future nuclear plants.”

In April the same team showed how graphene could be used as a ‘sieve’ to filter salt from seawater and make it drinkable. 

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