Markus Wehring scite author profile

Self-diffusion and relaxation time studies of C 3 to C 6 hydrocarbons adsorbed in the microporous metal-organic framework CuBTC were performed by nuclear magnetic resonance (NMR) in the temperature range of 193-373 K. The presence of paramagnetic copper species in the solid CuBTC framework leads to short longitudinal (T 1 ) and transverse (T 2 ) relaxation times of the hydrocarbons with typical values of T 1 j 10 ms and T 2 j 3 ms. Under these conditions, pulsed field gradient (PFG) NMR self-diffusion studies could only be performed at short observation times using the primary spin echo sequence with high-intensity pulsed magnetic field gradients. The obtained temperature dependent self-diffusion coefficients were analyzed using an Arrhenius approach. The activation energies of the alkanes are in the range of 6.5-8.5 kJ/mol, increasing slightly with increasing number of carbon atoms. Significantly higher values were found for propene (13.2 kJ/mol) and 1-butene (15.0 kJ/mol). These tendencies are consistent with corresponding measurements of heats of adsorption and with data obtained in molecular dynamics (MD) simulations. The MD simulations show a strong dependence of the heat of adsorption and diffusion on loading and temperature. This is caused by the preferential adsorption of small alkanes such as propane and butane in the side pockets of the CuBTC structure at low loading and temperature.

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Self-Diffusion of Chain Molecules in the Metal–Organic Framework IRMOF-1: Simulation and Experiment

Ford

Dubbeldam

Snurr

et al. 2012

J. Phys. Chem. Lett.

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Metal-organic frameworks (MOFs) possess characteristics, such as tunable pore size and chemical functionality, that make them attractive candidates for separations, catalysis, gas storage, and sensing applications. The rate of diffusion of guest molecules in the pores is an important property for all of these potential applications. In this work, the self-diffusion of hydrocarbons in IRMOF-1 was studied as a function of chain length with a combination of molecular dynamics simulations and pulsed field gradient NMR experiments. Excellent agreement is seen between the experiments and simulations, and the self-diffusion coefficients in IRMOF-1 are on the same order as those in the bulk liquid. Additionally, the effect of concentration on diffusivity was found to be very small for low to moderate loadings. Molecular dynamics simulations also provided insights about the preferential diffusion pathways of these guests in IRMOF-1.

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Markus Wehring

Self-Diffusion Studies in CuBTC by PFG NMR and MD Simulations

Self-Diffusion of Chain Molecules in the Metal–Organic Framework IRMOF-1: Simulation and Experiment

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