Small modular reactors offer a promising solution to the energy challenges in the data centre sector and power from advanced nuclear technologies could revolutionise the energy landscape - but educating decision makers is critical to advancing their deployment, according to a white paper from global industrial technology company Schneider Electric.
Data centres are central to driving the electrification and digitisation of the global economy, and have been the primary instruments of the increased adoption of artificial intelligence (AI), authors Marcin Wegrzyn and Steven Carlini say in Small Modular Nuclear Reactors Suitability for Data Centers. However, they are impacting energy demand in unprecedented ways.
Data centres are “singularly focused on reducing their own carbon footprint”, looking at multiple paths forward including increasing use of renewable energy and the introduction of efficient cooling technologies. But consistent power availability is becoming a serious concern, and sourcing local power is a challenge, with power purchase agreements (PPA) that were initially designed to drive adoption of renewables falling short of closing the gap between demand and availability.
“The sector needs alternatives. Nuclear can fill the gap,” the paper says.
As the demand for energy-efficient, reliable and sustainable power solutions for data centres continues to grow, small modular reactors (SMRs) “continue to emerge as a promising alternative to current constraints”, the paper says, offering a “compelling mix of lower capital costs, shorter deployment times and significant environmental benefits”. They offer the potential for reliable, low-carbon energy supply to data centres, with the potential for enhanced operational safety and improved energy resiliency compared to renewable alternatives, while their scalable design and advanced risk mitigation protocols may offer reduced environmental impacts. However, it notes, SMRs “are still unproven at scale”.
The paper sets out a list of considerations would-be adopters of SMRs for data centres should bear in mind when determining whether the technology would meet the needs of their project. These include, amongst other things: power needs, including prime and back-up power; availability options including regulatory restrictions; safety, siting and security assessments; time to deployment including regulatory approvals and construction; and environmental and sustainability considerations.
“SMR technology has matured, and their safety and reliability claims have data centre operators intrigued,” the paper concludes. “While there is much excitement for the technology, it must be proven before regulators allow for mass deployments.” It goes on to note that “the industry is in the process of establishing an optimised deployment model allowing for effective adoption of modular technology in the data centre industry.”
“Where modular reactors can work best is in concert with renewable resources as a complementary generation technology for green power. Additionally, and it goes without saying, every new technology requires a thorough vetting. In this case, an SMR evaluation would also include a security and risk assessment, as dictated by the data centre operator and its partners to address any local and national concerns,” it adds.
The data centre industry “will need to consider higher upfront costs” for nuclear but it is the “most realistic path” to meeting sustainability commitments, the paper says. “Safe and resilient reactors deployed onsite or as grid infrastructure may be a remedy to power shortages if regulatory and manufacturing regimes become standardised across geographies.”
Earlier this year, SMR developer Terrestrial Energy signed an agreement with Schneider to collaborate on developing zero-carbon energy solutions for industrial facilities and large data centres based on Terrestrial’s Integral Molten Salt Reactor.
Okay, so then since you seem so knowledgeable about how fantastic it is, please describe the current standards on nuclear waste disposal and how efficient it is.
Everything I’ve seen up to this point is contrary and the inability to find a good central location (like the whole Yucca Mountain debacle exemplifies the still existing problem: no one wants it in their back yard.
Are you suggesting the ponds and and other temporary measures that currently exist are a fine way to do business?
Yucca mountain is a political problem, not a technical one. But sure, if you want examples of good practice, I refer to COVRA in the Netherlands, where I had a tour a few months ago. Very interesting facility. If you want a deep geological repository, there is Onkalo in Finland. I’m not a fan of dedicated DGRs, but since it’s around, we might as well use it I guess.
In my view, should you care, we’re not going to put away the spent fuel at all in these DGRs, but recycle them in until we used all of the fuel. At this point there actual waste, should we no longer be able to recycle this, is around 1% of the current ‘waste’ in volume and consists solely of short lived isotopes remaining radioactive for around 300 years. If you want to bury that, sure, I guess.
But please, now you tell us more about how fantastic the waste management is of the arsenic mining tailings in China, which are a result of digging for rare Earths to make solar panels. I look forward to it!
Perhaps I should have been more clear: show me a good example in the US. I don’t have concerns on European regulation or methods. I also don’t doubt China is worse, but that’s for them to deal with.
Edit: also, what gave you the impression I thought it was a technical problem? Of course it’s a political problem. Humans being irresponsible cannot be fixed by technical means.