Incremental increases in material production won't significantly move the needle on energy consumption. The next 10x in per capita energy use will be driven by two main factors: expanding aviation to billions of people and the explosive growth of AI compute, which acts as a 'per capita' increase in intelligence.
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The primary bottleneck for scaling AI over the next decade may be the difficulty of bringing gigawatt-scale power online to support data centers. Smart money is already focused on this challenge, which is more complex than silicon supply.
The primary constraint on AI development is shifting from semiconductor availability to energy production. While the US has excelled at building data centers, its energy production growth is just 2.4%, compared to China's 6%. This disparity in energy infrastructure could become the deciding factor in the global AI race.
Pat Gelsinger contends that the true constraint on AI's expansion is energy availability. He frames the issue starkly: every gigawatt of power required by a new data center is equivalent to building a new nuclear reactor, a massive physical infrastructure challenge that will limit growth more than chips or capital.
The International Energy Agency projects global data center electricity use will reach 945 TWH by 2030. This staggering figure is almost twice the current annual consumption of an industrialized nation like Germany, highlighting an unprecedented energy demand from a single tech sector and making energy the primary bottleneck for AI growth.
The exponential growth of AI is fundamentally constrained by Earth's land, water, and power. By moving data centers to space, companies can access near-limitless solar energy and physical area, making off-planet compute a necessary step to overcome terrestrial bottlenecks and continue scaling.
The projected 80-gigawatt power requirement for the full AI infrastructure buildout, while enormous, translates to a manageable 1-2% increase in global energy demand—less than the expected growth from general economic development over the same period.
Most of the world's energy capacity build-out over the next decade was planned using old models, completely omitting the exponential power demands of AI. This creates a looming, unpriced-in bottleneck for AI infrastructure development that will require significant new investment and planning.
Unlike prior technological inputs like energy, which required machinery to be useful, AI compute can be added directly to the economy to strengthen it. Simply increasing compute improves product quality and expands user access simultaneously, acting as a direct economic force multiplier without traditional bottlenecks.
OpenAI's partnership with NVIDIA for 10 gigawatts is just the start. Sam Altman's internal goal is 250 gigawatts by 2033, a staggering $12.5 trillion investment. This reflects a future where AI is a pervasive, energy-intensive utility powering autonomous agents globally.
As hyperscalers build massive new data centers for AI, the critical constraint is shifting from semiconductor supply to energy availability. The core challenge becomes sourcing enough power, raising new geopolitical and environmental questions that will define the next phase of the AI race.
