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US Firms Develop Small Modular Reactors for Cheaper, Flexible Nuclear Power

US companies are developing small modular reactors (SMRs) to address high costs and licensing delays in nuclear power. SMRs have capacities of 300 MW or less and use modular design for faster construction. Microreactors under 20 MW can power remote areas, AI systems, and data centers. The US Department of Energy has allocated $900 million in funding and launched a pilot program to accelerate SMR development.

Key Points: US Companies Develop Small Modular Reactors for Nuclear Power

  • SMRs have capacity of about 300 MW or less, reducing capital costs
  • Modular design allows factory assembly, cutting construction time
  • Microreactors (20 MW or less) support remote areas and AI systems
  • DOE announced $900 million funding and pilot program for SMR tech
3 min read

US companies developing small modular reactors to cut costs, boost flexibility in nuclear power: Report

US companies are developing small modular reactors (SMRs) to cut costs and boost flexibility in nuclear power, overcoming challenges of traditional plants.

"Several companies are developing new small modular reactor (SMR) designs aimed at reducing capital costs and increasing siting flexibility, challenges associated with traditional nuclear power - US EIA"

New Delhi, April 30

Several companies in the United States are developing small modular reactors as a new approach to nuclear energy, aimed at reducing capital costs and improving flexibility in deployment, according to a report by the U.S. Energy Information Administration.

The report noted that the US currently operates about 98 gigawatts (GW) of nuclear generating capacity, but very little new capacity has been added in recent decades due to high capital costs and long licensing processes. SMRs are being seen as a solution to these challenges.

Unlike traditional large-scale nuclear reactors, which typically have a capacity between 550 megawatts (MW) and 1,500 MW per unit, SMRs have a capacity of about 300 MW per unit or less. Their modular design allows components to be factory-assembled and shipped to construction sites, which could help reduce construction time and costs.

US EIA said, "several companies are developing new small modular reactor (SMR) designs aimed at reducing capital costs and increasing siting flexibility, challenges associated with traditional nuclear power".

Different SMR designs use a variety of cooling technologies, including light water, gas, liquid metal and molten salt. Some designs use high-assay low-enriched uranium (HALEU), which is enriched between 5 per cent and under 20 per cent uranium-235, compared to the lower enrichment used in current reactors. This allows for improved efficiency, smaller reactor size and reduced nuclear waste.

A subset of SMRs, known as microreactors, generally have a capacity of 20 MW or less and can operate independently or as part of a microgrid. These smaller systems are particularly useful for remote areas or locations that lack the infrastructure to support large nuclear plants.

The report highlighted that SMRs and microreactors can also support emerging applications such as powering artificial intelligence systems, data centres and other industrial activities where grid connectivity may not be required.

The report also detailed advanced reactor types such as high-temperature gas reactors, molten salt reactors and sodium-cooled reactors, which can operate at higher temperatures and offer potential improvements in efficiency and industrial use.

Government support for SMR development in the US has been increasing. In March 2025, the US Department of Energy (DOE) reissued a tender for USD 900 million in funding to promote SMR technologies. The DOE also launched the Energy Reactor Pilot Program in June 2025 to accelerate testing of advanced reactors.

So the report suggests that SMRs and microreactors could play a key role in the future of nuclear energy by offering more flexible, cost-effective and scalable solutions compared to traditional nuclear power plants.

- ANI

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Reader Comments

P
Priya S
The potential for microreactors to power AI systems and data centers is fascinating 🇮🇳. Imagine pairing these with our solar farms for hybrid clean energy! However, we must ensure stringent safety protocols - one accident could set back public acceptance for decades. Nuclear is clean but needs careful handling.
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James A
SMRs could be game-changers for developing nations like India where land is scarce and grid infrastructure is patchy. Factory assembly reduces construction risk - something our nuclear projects have struggled with. But cost per MW needs to come down significantly for mass adoption. $900m DOE funding shows US is serious about this.
S
Siddharth J
Smart move by the US to revive nuclear through modular approach. But I'm concerned about HALEU fuel - it's enriched to 20% which is weapons-grade threshold. Proliferation risks are real. India should focus on thorium-based reactors instead, which we have abundant reserves. That's our strategic advantage! ☢️
K
Kavya N
The idea of microreactors for remote areas is exciting for places like Ladakh or Northeast where diesel generators are the norm. Clean power without transmission lines! But let's be honest - nuclear waste remains an unsolved problem globally. We need better disposal solutions before mass deployment. Also, local communities must be consulted, not imposed upon.
M
Michael C
India already operates small reactors (like the 220 MW PHWRs) so SMRs aren't entirely new for us. The modular construction approach is what's novel - could cut our 10-year project timelines in half! The US DOE funding is good, but India should also partner with Russia or France who have advanced SMR programs. Don't put all eggs in one

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