📊 Full opportunity report: The gigawatt gap. Why China is structurally positioned for AI power and the US is engineering around its grid. on ThorstenMeyerAI.com — validation score, market gap, and execution plan.

China is deploying AI data centers at gigawatt-scale capacities through centralized planning and extensive renewable energy infrastructure, challenging the US’s dominance at this critical physical layer of AI infrastructure development.

Recent analysis by Thorsten Meyer explains that while the US leads in chips, models, and AI applications, it faces significant constraints at the power delivery layer due to regulatory, permitting, and grid fragmentation issues. In contrast, China’s approach leverages a centralized infrastructure system, with the NDRC’s Eastern Data Western Compute initiative routing demand across 45 ultra-high-voltage transmission projects, enabling the transfer of over 340 GW of capacity. In 2025, China added approximately 430 GW of wind and solar power—eight times the US’s renewable additions—pushing total renewable capacity to over 1.8 TW and overall capacity to nearly 3.89 TW.

Chinese AI chips, such as Huawei’s Ascend 910C, perform at roughly 60% of US chips like the NVIDIA H100, but the Chinese system compensates by substituting raw power for chip performance. This structural advantage stems from China’s centralized planning, extensive renewable infrastructure, and vast transmission network, which collectively enable deploying less efficient chips across more power capacity without the same regulatory constraints faced by the US.

Implications of the Gigawatt Power Gap in AI Infrastructure

This structural difference in infrastructure could redefine global AI leadership. China’s ability to deploy AI at gigawatt scales, supported by renewable energy and centralized planning, may offset the US’s technological edge in chip performance. The outcome will influence who controls the physical layer of AI deployment, with potential long-term impacts on innovation, cost, and geopolitical influence.

US and China Approaches to AI Infrastructure Development

The US has built an AI infrastructure stack focused on chips, models, and software, but faces bottlenecks at the physical power delivery layer due to grid constraints and regulatory complexity. Major US data centers now require 100 MW to start and up to 2 GW at full buildout, with a backlog of interconnection requests exceeding 2,300 GW. Meanwhile, China’s strategy involves large-scale renewable generation combined with ultra-high-voltage transmission to supply AI data centers across vast distances, effectively bypassing regulatory and transmission bottlenecks. This approach is enabled by centralized planning and rapid renewable deployment, with China adding about 8 times more renewable capacity in 2025 than the US.

“The US infrastructure is constrained at the power delivery layer, while China’s centralized system and renewable buildout enable gigawatt-scale deployment that bypasses many US bottlenecks.”

— Thorsten Meyer

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Unclear Impact of Efficiency Gains and Policy Changes

It remains uncertain whether US efforts to improve chip efficiency and reform infrastructure permitting will close the gigawatt gap or whether China’s centralized approach will maintain its advantage. The long-term effects of these structural differences on global AI leadership are still developing and depend on future policy, technological, and geopolitical developments.

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Potential Developments in US and Chinese AI Infrastructure Strategies

Over the next 24 months, attention will focus on whether the US can implement regulatory reforms, improve infrastructure permitting, or develop new energy solutions to overcome power bottlenecks. Simultaneously, China’s continued renewable expansion and infrastructure investments will be monitored to assess whether their centralized approach sustains its competitive edge. The outcome will shape the global AI deployment landscape and influence future technological and geopolitical balances.

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Key Questions

Why does the US face constraints at the power layer for AI data centers?

The US’s fragmented grid system, regulatory hurdles, and permitting delays create bottlenecks that limit the scale and speed of deploying gigawatt-scale AI data centers.

How is China able to deploy AI infrastructure at such large scales?

China’s centralized planning, extensive renewable energy buildout, and ultra-high-voltage transmission network allow for large-scale power transfer and deployment of AI data centers across vast distances.

Does chip performance still matter in AI deployment?

Yes, but at the system level, the total power throughput becomes a critical constraint, meaning that raw chip performance is less decisive than the ability to supply sufficient power at scale.

Could the US close the gigawatt gap through efficiency improvements?

It is uncertain; efficiency gains in chips and infrastructure reform could help, but structural constraints may limit the extent of closing the gap compared to China’s centralized approach.

What are the long-term implications of these structural differences?

The outcome will influence which country leads in AI deployment, innovation, and geopolitical influence, depending on whether power infrastructure or chip performance becomes the dominant limiting factor.

Source: ThorstenMeyerAI.com