Litcius/Paper detail

Diffusion and reaction in pore hierarchies by the two-region model

Seungtaik Hwang, Jörg Kärger, Erich Miersemann

2021Adsorption13 citationsDOIOpen Access PDF

Abstract

Abstract The two-region (“Kärger”) model of diffusion in complex pore spaces is exploited for quantitating mass transfer in hierarchically organized nanoporous materials, consisting of a continuous microporous bulk phase permeated by a network of transport pores. With the implications that the diffusivity in the transport pores significantly exceeds the diffusivity in the micropores and that the relative population of the transport pores is far below that of the micropores, overall transport depends on only three independent parameters. Depending on their interrelation, enhancement of the overall mass transfer is found to be ensured by two fundamentally different mechanisms. They are referred to as the limiting cases of fast and slow exchange, with the respective time constants of molecular uptake being controlled by different parameters. Complemented with reaction terms, the two-region model may equally successfully be applied to the quantitation of the combined effect of diffusion and reaction in terms of the effectiveness factor. Generalization of the classical Thiele concept is shown to provide an excellent estimate of the effectiveness factor of a chemical reaction in hierarchically porous materials, solely based on the intrinsic reaction rate and the time constant of molecular uptake relevant to the given conditions.

Topics & Concepts

Mass transferThermal diffusivityMicroporous materialDiffusionNanoporousThermodynamicsLimitingMass transportPopulationGeneralizationChemistryMolecular diffusionReaction rate constantPhase (matter)Porous mediumConstant (computer programming)PorosityChemical physicsKineticsPhysicsOrganic chemistryMathematicsEngineering physicsDemographyMathematical analysisQuantum mechanicsMechanical engineeringOperations managementEngineeringProgramming languageSociologyMetric (unit)Computer scienceEconomicsZeolite Catalysis and SynthesisMesoporous Materials and CatalysisMetal-Organic Frameworks: Synthesis and Applications