Phase equilibrium modeling advances subsurface energy transition for a carbon-resilient future

Unofficial AI-generated summary based on the public title and abstract. Not an official translation.

🔬研究者:Researchers in CCUS and hydrogen storage will find a systematic review of phase equilibrium calculation methods and identification of key gaps to address.

🏢実務担当者:Engineers in subsurface energy projects can use the review to understand the state-of-the-art in modeling and the limitations of current equations of state.

🏛政策担当者:Policymakers supporting carbon capture and hydrogen storage will gain insight into the technical challenges that need further R&D investment.

Subsurface energy transition aims to mitigate climate change impacts by reducing carbon emissions while addressing energy needs through utilization of sustainable subsurface resources. It involves harnessing underground space for energy production and storage, encompassing strategies like sustainable recovery of unconventional resources, carbon capture, utilization and storage (CCUS), H 2 geological storage and geothermal development, etc. A swift and scalable deployment of the subsurface energy transition portfolios necessitates significant numerical endeavors wherein modelling the complex phase phenomena remains a practical challenge. Herein this paper examines literature in numerical phase equilibrium calculations, focusing on advancements in thermodynamic models and multiphase flash calculations, particularly in the context of energy transition in the subsurface domain for a carbon-resilient future, and the review is focused on vapor -liquid equilibrium. Methodologies for phase stability test, adjustments in phase behavior based on thermodynamics, developmental process of algorithms for phase equilibrium calculations, and applications in the energy field are covered. The application of phase behavior numerical calculation in developing unconventional oil and gas resources, CCUS, H 2 geological storage and geotherm are highlighted. It is found that although many EoSs merged with various modified parameters under certain conditions, which based on PR or other EoSs from last century, there is no such simplified representative equation with a broader application range. Moreover, lacking experimental results limits the verification of phase equilibrium calculation and data-driven model training. Thus, the phase equilibrium in subsurface energy still needs efforts to engage. In addition, methodological gaps and potential development paths are identified and suggested, aims to shed light upon the development in phase equilibrium calculations in the context of subsurface energy transition for promoting a carbon-conscious world. • Provides a comprehensive review of phase equilibrium modeling for subsurface energy transition applications. • Identifies key methodological gaps: the lack of a broadly applicable EoS and insufficient data fordata-driven methods. • Integrates classical thermodynamic approaches with emerging data-driven techniques under extreme subsurface conditions. • Proposes actionable research pathways to advance phase equilibrium modeling for subsurface energy technologies.

• openalex https://doi.org/10.1016/j.jcou.2026.103421first seen 2026-05-15 17:00:37