The company's concept of underground gravity storage wasn't a new invention but a rediscovery of U.S. DOE research from the 1980s. This research was abandoned when nuclear power expansion stopped, creating a forgotten opportunity that became viable again with the rise of renewables and their storage needs.
Related Insights
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.
Shure's founders pivoted back to their original EOR concept, which failed years prior due to a lack of automation infrastructure. The recent maturity of AI agents and stablecoin rails made the initial vision feasible, showing that timing and technological readiness are critical for an idea's success.
Instead of presenting its gravity storage as entirely novel, Terrament frames it as replicating pumped hydro—which accounts for 90% of global energy storage. This analogy helps stakeholders understand the concept by grounding it in a dominant, proven technology, thereby reducing perceived risk and accelerating acceptance.
The massive energy consumption of AI has made tech giants the most powerful force advocating for new power sources. Their commercial pressure is finally overcoming decades of regulatory inertia around nuclear energy, driving rapid development and deployment of new reactor technologies to meet their insatiable demand.
Instead of focusing only on new technology, it's crucial to see how old technologies disrupt industries in new ways. Mala Gaonkar cites lithium-ion batteries, invented in 1976, revolutionizing the modern auto industry, and gaming GPUs from the past now powering the AI boom.
For high-capital, long-lifespan projects like energy storage, leveraging proven, simple technologies is superior to complex, novel solutions. This approach ensures robustness and hits low economic targets, which is more critical than creating 'fancy' factory-built tech for this specific application.
Facing immense electricity needs for AI, tech giants like Amazon are now directly investing in nuclear power, particularly small modular reactors (SMRs). This infusion of venture capital is revitalizing a sector that has historically relied on slow-moving government funding, imbuing it with a Silicon Valley spirit.
TerraPower's advanced nuclear reactor design can use depleted uranium—currently treated as waste—as fuel. The amount of this material already stored in a single U.S. facility is sufficient to meet the entire planet's energy needs, carbon-free, for hundreds of years.
Base Power's founder identified the energy sector as ripe for disruption by pattern-matching. Like autos before Tesla or aerospace before SpaceX, energy was a massive, incumbent-dominated field that was not yet technology-focused, R&D-driven, or engineering-led.
Critics question whether deep tech startups are doing "novel science." However, the strategic goal is often not a new discovery, but making a proven but abandoned technology (like nuclear fission) economically viable and scalable again. This demonstrates that for reindustrialization, effective execution on proven tech can be more valuable than chasing purely scientific breakthroughs.
