Spontaneous liquid–gas imbibition for characterization of carbon molecular sieves

[Display omitted] ► Liquid–gas imbibition was proposed to characterize carbon molecular sieves (CMS). ► Micropore size of CMS was obtained by H2O–N2 imbibition and Monte Carlo simulation. ► Size-exclusion property of CMS was assessed by liquid–N2 imbibition. ► Effect of chemical vapor deposition on...

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Bibliographic Details
Published in:Journal of colloid and interface science 2012-07, Vol.377 (1), p.416-420
Main Authors: Su, Yanmin, Xu, Shaoping, Wang, Jifeng, Xiao, Ronglin
Format: Article
Language:English
Subjects:
adsorption
ambient temperature
benzene
carbon
Carbon molecular sieves
Chemistry
Colloidal state and disperse state
cyclohexanes
Exact sciences and technology
General and physical chemistry
imbibition
Micropore size
nitrogen
Porous materials
Size-exclusion property
Spontaneous liquid–gas imbibition
Surface physical chemistry
texture
vapors
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Summary:[Display omitted] ► Liquid–gas imbibition was proposed to characterize carbon molecular sieves (CMS). ► Micropore size of CMS was obtained by H2O–N2 imbibition and Monte Carlo simulation. ► Size-exclusion property of CMS was assessed by liquid–N2 imbibition. ► Effect of chemical vapor deposition on the pore texture of CMS was revealed. Spontaneous liquid–gas imbibition at 293.2K and 0.1MPa was conducted to assess the micropore size and size-exclusion property of carbon molecular sieves (CMS). The CMS were firstly saturated with N2 and then immersed into water. The volume of gas recovered by the water imbibition was measured and applied to evaluate the density of the N2 adsorbed in the CMS. The micropore size of the CMS was determined by comparing the N2 density from the water–N2 imbibition with that calculated by grand canonical simulation. The micropore size evaluated by the liquid–gas imbibition coincides with that obtained by N2 adsorption at ambient temperature. The size-exclusion property of the CMS was estimated through comparing the N2 recovery by imbibition of liquids with increasing molecular dimensions, that is, water, benzene, and cyclohexane. The amount of N2 recovered from benzene imbibition is dramatically less than that from the water imbibition, showing that the dominated micropore size of the CMS is smaller than 0.37nm. Furthermore, the effect of chemical vapor deposition treatment on the porous texture of the CMS was revealed by the liquid–gas imbibition.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2012.03.037