Spectroscopic Mesopore Size Characterization and Diffusion Measurement in Closed Porosity by Xenon NMR

Nuclear magnetic resonance measurements of 129Xe chemical shifts in a large variety of nonionic calibrated microporous and mesoporous silica glasses with open porosity provide a calibration of spectroscopic mesopore size measurements. The pore size dependence of the xenon chemical shift is quantitat...

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Veröffentlicht in:	Langmuir 2000-12, Vol.16 (26), p.10193-10197
Hauptverfasser:	Cros, F, Korb, J.-P, Malier, L
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description	Nuclear magnetic resonance measurements of 129Xe chemical shifts in a large variety of nonionic calibrated microporous and mesoporous silica glasses with open porosity provide a calibration of spectroscopic mesopore size measurements. The pore size dependence of the xenon chemical shift is quantitatively interpreted by considering both fast exchange and van der Waals interactions at the surface, which cause chemical shifts. The temperature dependence of the chemical shift supports the proposed model and characterizes the enthalpy of adsorption at the pore surface. The xenon NMR measurement is also useful for very low or even quasi-closed porous systems and may provide assessment of the macroscopic xenon diffusion coefficient in xerogels.
doi_str_mv	10.1021/la000322g
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title	Spectroscopic Mesopore Size Characterization and Diffusion Measurement in Closed Porosity by Xenon NMR
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