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Main Authors: Fang, Zhicong, Zhang, Boyu, Shang, Jin, Ma, Jiaze
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.13114
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author Fang, Zhicong
Zhang, Boyu
Shang, Jin
Ma, Jiaze
author_facet Fang, Zhicong
Zhang, Boyu
Shang, Jin
Ma, Jiaze
contents AI data centers (AIDCs) are rapidly increasing electricity demand and associated CO2 emissions, yet they also generate continuous low-grade waste heat. Here, we assess whether this heat can be upgraded by heat pumps to drive direct air capture (DAC) and reduce the climate impact of AI infrastructure. We develop a thermodynamically integrated DAC-AIDC system and conduct a region-resolved assessment across the United States, accounting for AIDC capacity, server composition, local climate, electricity prices, and grid carbon intensity. We find that AIDC waste heat can substantially improve net CO2 removal and lower the levelized cost of capture. In carbon-intensive regions, integration can flip DAC from net-positive to net-negative. Under a 2030 scenario with more GPU-intensive AIDCs and cleaner grids, several states achieve removal ratios above 1, indicating that integrated systems can offset their own operational emissions and deliver additional carbon removal.
format Preprint
id arxiv_https___arxiv_org_abs_2605_13114
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Recasting AI Data Centers as Engines for Carbon Removal
Fang, Zhicong
Zhang, Boyu
Shang, Jin
Ma, Jiaze
Optimization and Control
AI data centers (AIDCs) are rapidly increasing electricity demand and associated CO2 emissions, yet they also generate continuous low-grade waste heat. Here, we assess whether this heat can be upgraded by heat pumps to drive direct air capture (DAC) and reduce the climate impact of AI infrastructure. We develop a thermodynamically integrated DAC-AIDC system and conduct a region-resolved assessment across the United States, accounting for AIDC capacity, server composition, local climate, electricity prices, and grid carbon intensity. We find that AIDC waste heat can substantially improve net CO2 removal and lower the levelized cost of capture. In carbon-intensive regions, integration can flip DAC from net-positive to net-negative. Under a 2030 scenario with more GPU-intensive AIDCs and cleaner grids, several states achieve removal ratios above 1, indicating that integrated systems can offset their own operational emissions and deliver additional carbon removal.
title Recasting AI Data Centers as Engines for Carbon Removal
topic Optimization and Control
url https://arxiv.org/abs/2605.13114