CO2LOGIX: A first-order model of pressure-constrained CO2 geological storage growth at the basin scale

[Geoengineering News]

https://www.sciencedirect.com/science/article/pii/S1750583626000423?via%3Dihub

Authors: Iain de Jonge-Anderson, Gareth Johnson, Juan Alcalde, Jennifer J. Roberts

12 February 2026

https://doi.org/10.1016/j.ijggc.2026.104608

Highlights

•Developed CO2LOGIX, a fast basin-scale pressure-growth model for CO2 storage.

•Combines analytical pressure solution with logistic growth curve.

•Quantifies capacity for the UK accounting for basin-scale pressure response.

•Finds ∼ 12 GtCO2 of storage is achievable in 100 years, without mitigation, under pragmatic growth rates.

•Reveals trade-off between rapid CCS expansion and sustainable pressure behaviour.

Abstract

Subsurface pressure increases from CO2 injection can constrain injectivity and operating margins, reducing the dynamic capacity of CO2 geological storage systems. Engineered pressure management approaches are effective but carry additional cost and risk. Understanding the magnitude, interaction and evolution of these effects at the regional and multi-project scale is limited by computational demands and uncertainty over future deployment trajectories. This presents a limitation for climate-policy-informing frameworks such as Integrated Assessment Models (IAMs), which typically consider only static capacity in carbon capture and storage technology growth. We present CO2LOGIX, a new model which evaluates the scale of subsurface pressure buildup under different growth trajectories with computational efficiency. The model combines well-established analytical solutions describing pressure diffusion in the subsurface with a flexible logistic growth model, which informs well deployment rates and can be adjusted to reflect realistic development scenarios. We demonstrate the value of CO2LOGIX through a UK case study. In a modelled scenario based on historic industry growth rates, unmitigated pressure reaches upper bounds after 83 years, with ∼ 12 GtCO2 stored by 2100 – well above national targets of 4–6 GtCO2. However, short-term storage rates remain low (5 MtCO2/year by 2030 and 30 MtCO2/year by 2050), below recommended targets. Faster growth scenarios cause earlier pressure limit breaches, reducing available unmitigated capacity or requiring costly mitigation. Our findings underscore the importance of incorporating realistic pressure feedbacks between injection rates and long-term storage capacity into IAMs. CO2LOGIX provides a new first-order framework to anticipate and manage pressure limits in large-scale CO2 storage deployment.

Source: ScienceDirect