The advance tackles two major environmental problems at once by making use of coal production waste and by significantly reducing the environmental impact of concrete production.
The strong, durable concrete uses fly ash as a binder and eliminates the use of environmentally intensive cement, according to researchers from Washington State University (WSU) in the US.
Production of traditional concrete, which is made by combining cement with sand and gravel, contributes between five and eight percent of greenhouse gas emissions worldwide.
That is because cement, the key ingredient in concrete, requires high temperatures and a tremendous amount of energy to produce.
Fly ash, the material that remains after coal dust is burned, meanwhile has become a significant waste management issue. More than 50 per cent of fly ash ends up in landfills, where it can easily leach into the nearby environment.
While some researchers have used fly ash in concrete, they have not been able to eliminate the intense heating methods that are traditionally needed to make a strong material.
“Our production method does not require heating or the use of any cement,” said Gang Xu, a graduate student at WSU.
The study, published in the journal Fuel, is also significant because the researchers are using nano-sized materials to engineer concrete at the molecular level.
“To sustainably advance the construction industry, we need to utilize the ‘bottom-up’ capability of nanomaterials,” said Shi.
The team used graphene oxide, a recently discovered nanomaterial, to manipulate the reaction of fly ash with water and turn the activated fly ash into a strong cement-like material.
The graphene oxide rearranges atoms and molecules in a solution of fly ash and chemical activators like sodium silicate and calcium oxide.
The process creates a calcium-aluminate-silicate-hydrate molecule chain with strongly bonded atoms that form an inorganic polymer network more durable than (hydrated) cement.
The team designed the fly ash concrete to be pervious, which means water can pass through it to replenish groundwater and to mitigate flooding potential.
Researchers have demonstrated the strength and behaviour of the material in test plots on the WSU campus under a variety of load and temperature conditions.
They are still conducting infiltration tests and gathering data using sensors buried under the concrete. They eventually hope to commercialise the patented technology.
“After further testing, we would like to build some structures with this concrete to serve as a proof of concept,” said Xu.