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Membrane metal wall

Hydrogen can permeate selectively dense metal membranes, behaviour that permits the separation of hydrogen from gas mixtures. The mass transfer mechanism consists of several steps dissociation of hydrogen molecules into atoms, interaction of hydrogen atoms with the metal surface and their adsorption, diffusion of hydrogen into the metal lattice, and desorption of hydrogen atoms from the other metal surface and their recombination into molecules.The overall transport process through the metal wall is called permeation and is ruled by the expression ... [Pg.609]

An obvious approach in evaluating the nanopore model would involve a measurement of the proton conductivity of a nanoporous layer with charged metallic walls as a function of the applied voltage. Proton concentration in a conductive nanoporous membrane is a function of (pP . Assuming bulk-like proton transport, the variation of... [Pg.226]

Equations 13.17 and 13.18 are obtained under the hypothesis, generally verified, that the adsorption/desorption constants (Ka, Ka, and then Ke) are equal for the two metal surfaces. Different values of these constants could be due to the diverse status of the surfaces with presence of impurities, blanketing of the membrane surface, and variation of the mgosity. Accordingly, the gradient of the hydrogen concentration in the metal wall is obtained by elaborating Equation 13.17 with 13.18 as follows ... [Pg.449]

In order to maintain a definite contact area, soHd supports for the solvent membrane can be introduced (85). Those typically consist of hydrophobic polymeric films having pore sizes between 0.02 and 1 p.m. Figure 9c illustrates a hoUow fiber membrane where the feed solution flows around the fiber, the solvent—extractant phase is supported on the fiber wall, and the strip solution flows within the fiber. Supported membranes can also be used in conventional extraction where the supported phase is continuously fed and removed. This technique is known as dispersion-free solvent extraction (86,87). The level of research interest in membrane extraction is reflected by the fact that the 1990 International Solvent Extraction Conference (20) featured over 50 papers on this area, mainly as appHed to metals extraction. Pilot-scale studies of treatment of metal waste streams by Hquid membrane extraction have been reported (88). The developments in membrane technology have been reviewed (89). Despite the research interest and potential, membranes have yet to be appHed at an industrial production scale (90). [Pg.70]

We use the casting process to make polymer films (less than 0.3 mm thick) and sheets (more than 0.3 mm thick) for such diverse end uses as cling wrap, merchandise bags, roofing membranes, landfill liners, and the interior walls of refrigerators. During chill roll casting, molten polymer is extruded as a curtain from a slot die onto a chilled metal roller where it solidifies. The product is transported over a series of rollers to a winder where it is wound up. [Pg.218]

Figure 5.5 Synthesis of an encapsulated metal catalyst by the LbL method with a different metal catalyst in the membrane walls. Reproduced by permission ofthe PCCP Owner Societies [58]. Figure 5.5 Synthesis of an encapsulated metal catalyst by the LbL method with a different metal catalyst in the membrane walls. Reproduced by permission ofthe PCCP Owner Societies [58].
As shown in Fig. 1 biosorption comprises a variety of processes including ion exchange, chelation, adsorption, and diffusion through cell walls and membranes all of which are dependent on the species used, the biomass origin and, and solution chemistry (Gavrilescu 2004). Biosorption is a fast and reversible process for removing toxic metal ions from solution. [Pg.72]

The behaviour of natural ligands has been discussed in Section 4.3.3. In addition to the direct effect of complexation that is related to a decrease in the free ion activity, it has been shown that some ligands, in particular the HS, can be sorbed directly to biological surfaces, in the presence or absence of the trace metal [228,229]. This result is likely due to the fact that HS and similar macromolecules contain hydrophobic moieties that facilitate their adsorption to the plasma membrane and cell wall [157,230,231]. Because adsorption is expected to occur primarily with sites that are independent of the transporters,... [Pg.480]

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See also in sourсe #XX -- [ Pg.60 , Pg.68 ]



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