Diffusion of CO 2 in ion-exchanged zeolites Rho studied by the ZLC technique

Mangano, Enzo, Brandani, Stefano, Lozinska, Magdalena M., Wright, Paul A.

16 October 2015

No description available.

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diffusion

transport

ddc:530

Formation of alpha-(Ti) phase on grain boundaries in Ti-Co alloys

Gornakova, Alena S., Prokofjev, Sergei I., Straumal, Boris B.

16 October 2015

No description available.

Diffusion

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diffusion

transport

ddc:530

Diffusion in Li x Na 2-x Ti 6 O 13 investigated with impedance spectroscopy

Volgmann, Kai, Bösebeck, Katharina, Heitjans, Paul

19 October 2015

No description available.

Diffusion

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diffusion

transport

ddc:530

7 Li ion diffusion in isotope-diluted glassy Li 2 Si 3 O7

Wohlmuth, Dominik, Epp, Viktor, Bauer, Ute, Welsch, Anna-Maria, Behrens, Harald, Wilkening, Martin

19 October 2015

No description available.

Diffusion

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diffusion

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ddc:530

Revealing Li + exchange in the beta-modification of Li 3 VF 6 by 6 Li 2D MAS NMR spectroscopy

Bottke, Patrick, Nakhal, Suliman, Lerch, Martin, Heitjans, Paul, Wilkening, Martin

26 October 2015

No description available.

Diffusion

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diffusion

transport

ddc:530

A new technique for the measurement of CO 2 diffusion in thin polymer films

Lee, M. Kathryn, Cundy, Stephen M., Calabro, David C., Li, Quanchang, Peiffer, Dennis

27 October 2015

No description available.

Diffusion

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diffusion

transport

ddc:530

Direct calculation of the thermodynamic correction factor, gamma, from molecular dynamics simulations

Schnell, Sondre Kvalvåg, Vlugt, Thijs J. H., Simon, Jean-Marc, Kjelstrup, Signe, Bedeaux, Dick

28 October 2015

No description available.

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diffusion

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ddc:530

Adsorption of organics on MSC5A in supercritical CO 2

Chihara, Kazuyuki, Ito, Shingo, Nagashima, Hideo, Hikita, Masayuki, Suzuki, Ryosuke

29 October 2015

Chromatographic measurements were made for the adsorption of benzene, toluene and m-xylene on molecular sieving carbon (MSC) in a supercritical fluid CO2 mixed with organics. A supercritical chromatograph packed with MSC was used to detect pulse responses of the organics. Adsorption equilibria and adsorption dynamic parameters for organics were obtained by moment analysis of the response peaks. Dependences of adsorption equilibrium constants, K*, and micropore diffusivity, D, on the amount adsorbed were examined. The dependencies of adsorption equilibrium constants, K*, and micropore diffusivities, D, for benzene, toluene and m-xylene, on the molarity of benzene over a range of temperature and pressure were obtained. Experimental results were simulated using the “Stop & Go” method as well as by molecular simulation.

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ddc:530

Dynamic correlations between susceptibility gradients and T 2 -relaxation as a probe for wettability properties of liquid saturated rock cores

Pavlin, Tina, Seland, John Georg

02 November 2015

We explore the use of correlations between susceptibility gradients, G0, and T2-relaxation (G0-T2), and show how the difference in response for oil and water with respect to G0 can be used for improved characterization of wettability of the internal surface in porous rock cores.

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diffusion

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ddc:530

A T 2 D TDNMR study of skin

Bent, Julian, Lee, Joanna, Benson, Tim

02 November 2015

T2D TDNMR data is used to improve the assignment of the location of water in in-vitro pig skin. Whilst the corresponding 1d experiments report broad distributions of T2 and D respectively, two water components are resolved in the T2D data and are assigned as intraand extra-cellular water by considering the peak intensities in; whole defatted skin, a dermatomed slice of the top 0.4mm (mostly epidermis) and the remaining sub layer (dermis). The relative proportion of fast relaxing/fast diffusing water is largest in the epidermis section (which has a close packed cellular structure) so is assigned as intra-cellular water. Whilst there is more slowly relaxing/slowly diffusing water in the dermis section (which has fewer cells within a collagen network) so this is assigned as extra-cellular water. The observation that intra-cellular water relaxes fastest, suggests that the skin cells contain more exchangeable species, through which the water can relax, than the extra-cellular network. This assignment is supported when resolution is lost on repeated freezing, i.e. the cell walls are broken. Resolution is also lost on increasing the diffusion time from 50 to 100 and 150ms. This is likely partly due to relaxation but also due to diffusion through the cell membranes during the experiment and gives a measure of the cell wall permeability.

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diffusion

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ddc:530