Today's nuclear energy boom is propelled by strong commercial demand from AI data centers and defense, not government R&D. This market-driven "demand pull" for energy is finally creating the business case for advanced and small modular reactors.

AI hyperscalers' urgent need for power makes them willing to pay a premium for rapid deployment (months vs. years). This high-margin initial market can fund the transition to factory-based mass production for nuclear energy, eventually allowing costs to drop for broader markets like utilities and industrial users.

The 40-year plateau in nuclear power wasn't driven by public fear after incidents like Chernobyl, but by the soaring costs of building massive, one-off reactors. The modern push for Small Modular Reactors (SMRs) aims to solve this fundamental economic problem through factory-based production.

In the 1970s, France built 57 reactors in 15 years through its government-led utility, which repeatedly built the same design. In contrast, the US's fragmented private utility system, with each company building different designs, failed to achieve similar cost reductions and scale.

Utilities are unwilling to fund new nuclear plants due to the high risk of budget overruns. The predicted 'renaissance' will only happen if the government steps in to backstop these projects, absorbing the excess financial risk to incentivize construction and ensure energy security.

After massive cost overruns on traditional nuclear projects, no utility will build a Small Modular Reactor (SMR) alone. The only viable path forward is for a tech giant to provide both a purchase agreement for the power and direct equity investment in the SMR manufacturer to fund capital expenditures.

The high costs of Georgia's recent Vogtle nuclear plant are often blamed on regulation. However, the primary drivers were project management and supply chain failures, like ordering the wrong rebar, which caused year-long delays due to a loss of institutional knowledge.

Unlike traditional nuclear power which involves building massive, site-specific projects, Radiant is treating reactors as mass-producible products. Their focus on smaller, mobile 1MW units prioritizes rapid deployability and mobility over raw power scale, enabling them to serve off-grid and remote use cases.

Most reactors marketed as SMRs are neither small enough for standard road transport nor truly modular. Their components, sourced from dozens of different factories, often fail to integrate on-site, leading to the same delays and cost overruns as large-scale projects. True modularity requires single-factory production.