Tortuosity measurement and the effects of finite pulse widths on xenon gas diffusion NMR studies of porous media

We have extended the utility of NMR as a technique to probe porous media structure over length scales of ∼100–2000 μm by using the spin 1/2 noble gas 129Xe imbibed into the system’s pore space. Such length scales are much greater than can be probed with NMR diffusion studies of water-saturated porou...

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Bibliographic Details
Published in:Magnetic resonance imaging 2001-04, Vol.19 (3), p.345-351
Main Authors: Mair, R.W., Hürlimann, M.D., Sen, P.N., Schwartz, L.M., Patz, S., Walsworth, R.L.
Format: Article
Language:English
Subjects:
Biological and medical sciences
Diffusion
Investigative techniques, diagnostic techniques (general aspects)
Life Sciences (General)
Magnetic Resonance Spectroscopy - methods
Medical sciences
Miscellaneous. Technology
Models, Theoretical
PGSE
Porosity
Porous media
Radiodiagnosis. Nmr imagery. Nmr spectrometry
Space life sciences
Tortuosity
Xenon
Xenon - chemistry
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Summary:We have extended the utility of NMR as a technique to probe porous media structure over length scales of ∼100–2000 μm by using the spin 1/2 noble gas 129Xe imbibed into the system’s pore space. Such length scales are much greater than can be probed with NMR diffusion studies of water-saturated porous media. We utilized Pulsed Gradient Spin Echo NMR measurements of the time-dependent diffusion coefficient, D(t), of the xenon gas filling the pore space to study further the measurements of both the pore surface-area-to-volume ratio, S/V p, and the tortuosity (pore connectivity) of the medium. In uniform-size glass bead packs, we observed D(t) decreasing with increasing t, reaching an observed asymptote of ∼0.62–0.65 D 0, that could be measured over diffusion distances extending over multiple bead diameters. Measurements of D(t)/D 0 at differing gas pressures showed this tortuosity limit was not affected by changing the characteristic diffusion length of the spins during the diffusion encoding gradient pulse. This was not the case at the short time limit, where D(t)/D 0 was noticeably affected by the gas pressure in the sample. Increasing the gas pressure, and hence reducing D 0 and the diffusion during the gradient pulse served to reduce the previously observed deviation of D(t)/D 0 from the S/V p relation. The Pade approximation is used to interpolate between the long and short time limits in D(t). While the short time D(t) points lay above the interpolation line in the case of small beads, due to diffusion during the gradient pulse on the order of the pore size, it was also noted that the experimental D(t) data fell below the Pade line in the case of large beads, most likely due to finite size effects.
ISSN:0730-725X
1873-5894
DOI:10.1016/S0730-725X(01)00247-8