4.6 Article

Measurement and modelling of the intra-particle diffusion and b-term in reversed-phase liquid chromatography

Journal

JOURNAL OF CHROMATOGRAPHY A
Volume 1637, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.chroma.2020.461852

Keywords

Intra-particle diffusion; Surface diffusion; Partitioning; Adsorption; Excess organic modifier

Funding

  1. Research Foundation Flanders (FWO) [12Y9818N]
  2. Camille and Henry Dreyfus Foundation

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New models for intra-particle diffusion in particle-packed reversed-phase liquid chromatography columns are proposed, dividing the mesoporous zone inside particles into four distinct regions. Experimental procedures and models are used to predict intra-particle diffusion and confirm that both adsorption- and partition-type models accurately simulate the behavior of test compounds. The major contributor to the intra-particle diffusion of retained compounds is the diffusion analytes undergo in the organic-modifier enriched zone surrounding the alkyl chains (partition model) or when adsorbed onto the alkyl chains (adsorption model), highlighting the role of surface diffusion in mass transfer in chromatography columns.
In an ongoing effort to better understand the underlying mechanisms of band broadening in particle-packed reversed-phase liquid chromatography columns, new models for intra-particle diffusion, representing an adsorption- and partition-type retention behavior, are proposed. These models assume the mesoporous zone inside the particles is subdivided in four distinct regions: a fraction f(1) filled with bulk mobile phase, a fraction f(2) enriched in pure organic modifier extending outside the stationary phase layer, a fraction f(3) comprising the liquid surrounding the alkyl chains and a fraction f(4) consisting of the stationary phase alkyl chains. Intra-particle diffusion is calculated as a residence time weighted average of the diffusion in these different regions. Experimental procedures and models are proposed to determine the volumes of these four regions and applied to three reversed-phase liquid chromatography columns with different pore sizes (80 angstrom versus 300 angstrom) and different stationary phase types (C-18 versus C-8). The newly proposed models are then applied to predict the intra-particle diffusion of butyrophenone across a wide range of retention factors (1 <= k <= 40) in each of these columns. These predictions are compared to experimental data that are extracted from the effective diffusion coefficients of butyrophenone obtained via peak parking experiments. It is demonstrated that both adsorption- and partition-type models for intra-particle diffusion model the actual behavior of the test compound well, and require the determination of only one (partition) or two (adsorption) fitting factors: the obstruction to free movement the analytes experience from the alkyl chains in the retained state (partition and adsorption) and in the unretained state (adsorption). Finally, it is demonstrated that the major contributor to the intra-particle diffusion of retained compounds (k > 2) is the diffusion these analytes undergo when retained in the organic-modifier enriched zone surrounding the alkyl chains (partition model) or when adsorbed onto the alkyl chains (adsorption model), confirming that surface diffusion plays an important role in the mass transfer of retained compounds in reversed-phase liquid chromatography columns. (C) 2020 Elsevier B.V. All rights reserved.

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