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Phase behavior of <i>n</i>-hexane confined in unconsolidated nanoporous media: an experimental investigation at varying pore sizes and temperatures

Keerti Vardhan Sharma, Rami M. Alloush, Omer Salim, Mohammad Piri

2024Physical Chemistry Chemical Physics15 citationsDOI

Abstract

, liquid-vapor phase transition, occurs at a lower pressure than its capillary condensation counterpart. The experimental findings demonstrate that the confinement effect becomes weaker in wider nanopores due to the reduced solid-fluid interactions in larger spaces. Furthermore, it is evident from isotherms that hexane rapidly approaches a supercritical-like state at high temperatures when confined in smaller pores, resulting in an ambiguous vapor-liquid phase transition. In contrast, this behavior disappears in larger pores at similar temperatures. Moreover, the present study compares the fully gravimetric adsorption method against the thermogravimetric approach. The results show that the fully gravimetric method, which directly measures the mass of the adsorbed or condensed fluids, provides significant advantages over the thermogravimetric counterpart. The findings of this study are expected to be of fundamental interest to a wide range of science and engineering communities concerned about the behavior of heavier hydrocarbons in various industrial applications, and modeling the confined phase behavior of fluids and developing robust equations of state (EOS).

Topics & Concepts

NanoporousMaterials scienceHexaneComposite materialPorous mediumChemical engineeringPhase (matter)Petroleum engineeringGeologyChromatographyNanotechnologyChemistryPorosityEngineeringOrganic chemistryMetal-Organic Frameworks: Synthesis and ApplicationsZeolite Catalysis and SynthesisPhase Equilibria and Thermodynamics
Phase behavior of <i>n</i>-hexane confined in unconsolidated nanoporous media: an experimental investigation at varying pore sizes and temperatures | Litcius