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Decompression-induced condensation of carbon dioxide: Experiments, and prediction of the supercooling limit using classical nucleation theory

Morten Hammer, Alexandra Metallinou Log, Han Deng, Anders Austegard, Svend Tollak Munkejord

2025Chemical Engineering Science10 citationsDOIOpen Access PDF

Abstract

• We predict the supercooling limit of COâ‚‚-rich gases for pipe decompression using CNT. • We employ multi-parameter equations of state to predict decompression and nucleation. • New full-bore decompression experiments with pure COâ‚‚ are conducted. • Supercooling-limit predictions demonstrate a mean absolute percentage deviation of 3 • Decompression curves are key to preventing running ductile fractures in pipes. This work investigates the nucleation of droplets from supercooled CO 2 and CO 2 -rich gas during decompression, using classical nucleation theory (CNT). We model the supercooling limit employing highly accurate equations of state and compare the result with nucleation pressures determined from experimental data. The present analysis is relevant for the safety assessment of pipelines containing gaseous CO 2 . Three new full-bore decompression experiments with pure CO 2 were conducted, incorporating high-speed pressure sampling and multiple sensors to achieve precise characterization of the decompression wave speed as a function of pressure. Additionally, eight experiments with pure CO 2 and nine with CO 2 -rich mixtures from the open literature were analysed. The homogeneous equilibrium model (HEM) and delayed homogeneous equilibrium model ( D-HEM ) were used to calculate the decompression wave speed down to the choking condition. Across all experiments, predictions based on the saturation pressure (applied in the HEM) consistently overestimated the experimentally determined nucleation values. In contrast, those based on the supercooling limit (applied in D-HEM ) showed a mean absolute percentage deviation of 3 % , with predictions randomly distributed around the experimental results.

Topics & Concepts

SupercoolingNucleationLimit (mathematics)CondensationCarbon dioxideThermodynamicsChemistryMaterials sciencePhysicsMathematicsOrganic chemistryMathematical analysisnanoparticles nucleation surface interactionsPhase Equilibria and ThermodynamicsGas Dynamics and Kinetic Theory
Decompression-induced condensation of carbon dioxide: Experiments, and prediction of the supercooling limit using classical nucleation theory | Litcius