Pressure-varying Langmuir parameters and stepped nitrogen adsorption on alumina and silica

Brown, Trevor C; Miron, David J; Fellows, Christopher M

doi:10.1039/C8CP06163G

Author(s)

Brown, Trevor C

Miron, David J

Fellows, Christopher M

Publication Date

2019-02-07

Abstract

Insights into surface structures and thermodynamics are provided for nitrogen adsorption on two nonporous alumina adsorbents and two macroporous silica adsorbents by modelling high-resolution data using the simple Langmuir isotherm equation combined with pressure-varying flexible least squares. The fitted parameters, maximum adsorption capacity and standard Gibbs energy change for each adsorbent show multiple steps that are assumed to be indicative of transitions to different complete monolayer and multilayer structures. Pressure-varying N₂ cross-sectional areas for three of the adsorbents are calculated by assuming that one of the steps is the Brunauer–Emmett–Teller monolayer with molecular area 16.2 Å². The silica with added octyldimethylsilyl groups has pressure-varying parameter profiles that differ from the other adsorbents and here the N₂ cross-sectional area is assumed to be 21.3 Å² to ensure consistency with the literature surface area. Seven monolayers and multilayers are identified across the four adsorbents, and corresponding molecular areas compare favourably with reported values. At low pressures, adsorption occurs at the strongest sites, and is localised and dependent on surface heterogeneity and topography. Up to five complete, two-dimensional lattice structures are apparent in the mid-pressure ranges. At high pressures, multilayers and liquefaction points are observed and are independent of surface composition and heterogeneity.

Citation

Physical Chemistry Chemical Physics, 21(5), p. 2558-2566

ISSN

1463-9084

1463-9076

Link

https://hdl.handle.net/1959.11/28102

Language

en

Publisher

Royal Society of Chemistry

Rights

CC0 1.0 Universal

Title

Pressure-varying Langmuir parameters and stepped nitrogen adsorption on alumina and silica

Type of document

Journal Article

Entity Type

Publication

Author(s)	Brown, Trevor C Miron, David J Fellows, Christopher M
Publication Date	2019-02-07
Abstract	Insights into surface structures and thermodynamics are provided for nitrogen adsorption on two nonporous alumina adsorbents and two macroporous silica adsorbents by modelling high-resolution data using the simple Langmuir isotherm equation combined with pressure-varying flexible least squares. The fitted parameters, maximum adsorption capacity and standard Gibbs energy change for each adsorbent show multiple steps that are assumed to be indicative of transitions to different complete monolayer and multilayer structures. Pressure-varying N₂ cross-sectional areas for three of the adsorbents are calculated by assuming that one of the steps is the Brunauer–Emmett–Teller monolayer with molecular area 16.2 Å². The silica with added octyldimethylsilyl groups has pressure-varying parameter profiles that differ from the other adsorbents and here the N₂ cross-sectional area is assumed to be 21.3 Å² to ensure consistency with the literature surface area. Seven monolayers and multilayers are identified across the four adsorbents, and corresponding molecular areas compare favourably with reported values. At low pressures, adsorption occurs at the strongest sites, and is localised and dependent on surface heterogeneity and topography. Up to five complete, two-dimensional lattice structures are apparent in the mid-pressure ranges. At high pressures, multilayers and liquefaction points are observed and are independent of surface composition and heterogeneity.
Citation	Physical Chemistry Chemical Physics, 21(5), p. 2558-2566
ISSN	1463-9084 1463-9076
Link	https://hdl.handle.net/1959.11/28102
Language	en
Publisher	Royal Society of Chemistry
Rights	CC0 1.0 Universal
Title	Pressure-varying Langmuir parameters and stepped nitrogen adsorption on alumina and silica
Type of document	Journal Article
Entity Type	Publication

Pressure-varying Langmuir parameters and stepped nitrogen adsorption on alumina and silica

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