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One promising form of clean energy that hasn’t attracted much media attention is produced by what’s called small modular reactors (SMRs), which generate enough nuclear power to run an industrial plant or cover the energy needs of a small rural community.

At a fraction of the size of a conventional nuclear power reactor — weighing between 200 and 500 tonnes and with a capacity of up to 300 megawatts — their modules can be manufactured in a factory and later transported to the site for final assembly and installation, leading to increased efficiency and improved return on investment.

According to the , these fission reactors can be installed in rural locations that aren’t suitable for larger nuclear plants, which aligns with and in remote communities. In some cases, says the commission, they have passive safety systems that can “eliminate or significantly lower the potential for unsafe releases of radioactivity to the environment and the public in case of an accident.” 

More than 80 designs have been developed in the United States, Argentina, China, Russia, South Korea and Canada — all inching towards regulatory approval sometime this decade.

At the forefront of SMR design in Canada is , a mechanical engineering professor at the º£½ÇÉçÇø, who recently received $2.5 million over the next three years from Natural Resources Canada’s and related programs and industry partnerships to develop and test advanced materials for use in Canadian-made, high-performance SMRs that operate at high temperatures.

“This is a critical part of Alberta’s energy future,” says Yakout. “Nuclear is considered one of the cleanest types of energy, and Alberta is well positioned to lead the SMR effort in Canada, if not in North America.”

Yakout’s team will include º£½ÇÉçÇø colleagues (Mechanical Engineering), (Chemical and Materials Engineering) and (Chemistry), working in collaboration with , , ,  and .

About a dozen doctoral students and postdoctoral fellows will also work on the project.

The research team will explore ways to make the containment material inside the fission reactors — which must hold up under temperatures as high as 850 degrees Celsius— less corrosive and more durable, while making manufacturing cheaper with less waste. They will begin by attempting to modify a superalloy used in conventional nuclear reactors, called , used to resist corrosion under extreme heat.

“We’re looking for ways to prevent materials degradation to increase the operational life of reactor components and reduce the refuelling intervals,” says Yakout. “High-temperature, corrosion-resistant materials will operate under extreme thermal stress conditions, which will add passive safety features to prevent accidents or leaks in reactors.”

Using a relatively new process called additive manufacturing, commonly known as 3D printing, “we are able to integrate design materials and manufacturing to make very complex structures,” he says.

To make the product commercially viable, the team is also exploring applications in other sectors such as defence, space and aerospace.

In its , the Alberta government calls the reactors “the next evolution in nuclear innovation and technology,” with the capacity to bring “safe and reliable, zero-emissions energy to power our communities, while meeting the demands of a growing economy and population.”

Working with industry and government partners, Yakout’s team is aiming for a high-performance standard in its materials design that will stand up to regulatory approval once the reactors are ready for deployment.

“We want to be sure that when the reactors are ready to go, we have all the regulations and licensing in place, and that the public is satisfied they are safe and clean."

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