Relaxation and diffusion studies of cyclohexane confined in MCM-41 by NMR

In this work the rotational and translational dynamics of cyclohexane confined in MCM-41 have been studied as a function of temperature by measuring intra-crystalline diffusivities and T 1 and T 2 relaxation times. The results are compared with values obtained for bulk cyclohexane and cyclohexane co...

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Bibliographic Details
Published inMicroporous and mesoporous materials Vol. 42; no. 1; pp. 89 - 96
Main Authors Gjerdåker, Lars, Aksnes, Dagfinn W., Sørland, Geir Humborstad, Stöcker, Michael
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Inc 2001
Elsevier
Subjects
Chemistry
Cyclohexane
Diffusion
Exact sciences and technology
General and physical chemistry
Ion-exchange
MCM-41
Other ion exchangers: preparations and properties
PFG-NMR
Relaxation
Surface physical chemistry
Relaxation
MCM-41
PFG-NMR
Diffusion
Cyclohexane
Hydrocarbon
Liquid solid adsorption
Pore structure
Surface layer
NMR spectrometry
Experimental study
Porous material
Mesoporosity
Molecular sieve
Relaxation time
Preparation
Pulsed field
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Summary:In this work the rotational and translational dynamics of cyclohexane confined in MCM-41 have been studied as a function of temperature by measuring intra-crystalline diffusivities and T 1 and T 2 relaxation times. The results are compared with values obtained for bulk cyclohexane and cyclohexane confined in 40 Å silica. T 1 was measured for three different samples, with three different filling grades of cyclohexane. The T 1 curves are continuous over the studied temperature region, and the slope is practically unchanged. However, a marked increase in T 1 with the degree of pore filling is seen owing to an increasing contribution from the bulk-like molecules at the interior of the pores. Only one surface component, attributed to the molecules at the pore walls, was observed when measuring the T 2 relaxation. The relatively narrow spin-echo signal and the long T 2 indicate that the liquid adsorbed on the pore surface does not freeze at all, even at temperatures far below the plastic-brittle solid transition point of the bulk material. The true intra-crystalline diffusivity was obtained by using the short diffusion time model and extrapolating to zero observation time. A high diffusion rate was observable over a wide temperature region, and the measured diffusivity is about three orders of magnitude larger than in the plastic phase of bulk cyclohexane.
ISSN:1387-1811
1873-3093
DOI:10.1016/S1387-1811(00)00310-3