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Electron membrane

Membrane Efficiency The permselectivity of an ion-exchange membrane is the ratio of the transport of electric charge through the membrane by specific ions to the total transport of electrons. Membranes are not strictly semipermeable, for coions are not completely excluded, particularly at higher feed concentrations. For example, the Donnan eqmlibrium for a univalent salt in dilute solution is ... [Pg.2030]

The use of a mixed oxygen ion-electronic conductor membrane for oxygen separation with direct reforming of methane, followed by the use of a mixed protonic-electronic membrane conductor for hydrogen extraction has also been proposed in the literature [34]. The products are thus pure hydrogen and synthesis gas with reduced hydrogen content, the latter suitable, for example, in the Fish-er-Tropsch synthesis of methanol [34]. [Pg.278]

By virtue of the membranes, the Fermi energy of the upper level translates into the Fermi energy at the electron membrane, whilst the Fermi energy of the lower level becomes the Fermi energy at the hole membrane. The difference between the Fermi energies of the two membranes is related to the voltage V between the contacts to the membranes by... [Pg.126]

Today, the majority of research investigations into CMRs are being conducted by many institutions, in addition to oil and chemical and utilities companies [5]. The use of mixed ionic-electronic membrane reactors for the partial oxidation of natural gas is undergoing active development by a number of consortia based around Air Products and Chemicals (USA), Praxair (USA), and/or Air Liquide (France). At present, the development of CMRs involving a pure ion-conducting electrolyte is restricted to a few reports of conceptual systems [12, 95]. [Pg.423]

Figure 2.1 Hydrogen transport through a dense mixed protonic-electronic membrane. Figure 2.1 Hydrogen transport through a dense mixed protonic-electronic membrane.
Dense electrolytes and mixed conducting (ionic and electronic) membranes. [Pg.324]

The platinum acts here merely as an electron membrane, its potential being determined by the concentration ratio of ferric and ferrous ions in the... [Pg.9]

Knoll G and Plattner H 1989 Ultrastructural analysis of biological membrane fusion and a tentative correlation with biochemical and biophysical aspects Electron Microscopy of Subcellular Dynamics ed H Plattner (London CRC) pp 95-117... [Pg.1650]

The spatial arrangement of atoms in two-dimensional protein arrays can be detennined using high-resolution transmission electron microscopy [20]. The measurements have to be carried out in high vacuum, but since tire metliod is used above all for investigating membrane proteins, it may be supposed tliat tire presence of tire lipid bilayer ensures tliat tire protein remains essentially in its native configuration. [Pg.2818]

A salient feature of natural surfaces is tliat tliey are overwhelmingly electron donors [133]. This is tlie basis for tlie ubiquitous hydrophilic repulsion which ensures tliat a cell can function, since massive protein-protein aggregation and protein-membrane adsorjition is tliereby prevented. In fact, for biomolecule interactions under typical physiological conditions, i.e. aqueous solutions of moderately high ionic strengtli, tlie donor-acceptor energy dominates. [Pg.2839]

Miscellaneous Applications. Ben2otrifluoride derivatives have been incorporated into polymers for different appHcations. 2,4-Dichloroben2otrifluoride or 2,3,5,6-tetrafluoroben2otrifluoride [651-80-9] have been condensed with bisphenol A [80-05-7] to give ben2otrifluoride aryl ether semipermeable gas membranes (336,337). 3,5-Diaminoben2otrifluoride [368-53-6] and aromatic dianhydrides form polyimide resins for high temperature composites (qv) and adhesives (qv), as well as in the electronics industry (338,339). [Pg.333]

These membranes mimic natural photosynthesis except that the electrons are directed to form hydrogen. Several sensitizers and catalysts are needed to complete the cycle, but progress is being made. Various siagle-stage schemes, ia which hydrogen and oxygen are produced separately, have been studied, and the thermodynamic feasibiHty of the chemistry has been experimentally demonstrated. [Pg.19]

Traditionally, the electron and proton transport pathways of photosynthetic membranes (33) have been represented as a "Z" rotated 90° to the left with noncycHc electron flow from left to right and PSII on the left-most and PSI on the right-most vertical in that orientation (25,34). Other orientations and more complex graphical representations have been used to depict electron transport (29) or the sequence and redox midpoint potentials of the electron carriers. As elucidation of photosynthetic membrane architecture and electron pathways has progressed, PSI has come to be placed on the left as the "Z" convention is being abandoned. Figure 1 describes the orientation in the thylakoid membrane of the components of PSI and PSII with noncycHc electron flow from right to left. [Pg.39]

Both PSI and PSII are necessary for photosynthesis, but the systems do not operate in the implied temporal sequence. There is also considerable pooling of electrons in intermediates between the two photosystems, and the indicated photoacts seldom occur in unison. The terms PSI and PSII have come to represent two distinct, but interacting reaction centers in photosynthetic membranes (36,37) the two centers are considered in combination with the proteins and electron-transfer processes specific to the separate centers. [Pg.39]

Electron Transport Between Photosystem I and Photosystem II Inhibitors. The interaction between PSI and PSII reaction centers (Fig. 1) depends on the thermodynamically favored transfer of electrons from low redox potential carriers to carriers of higher redox potential. This process serves to communicate reducing equivalents between the two photosystem complexes. Photosynthetic and respiratory membranes of both eukaryotes and prokaryotes contain stmctures that serve to oxidize low potential quinols while reducing high potential metaHoproteins (40). In plant thylakoid membranes, this complex is usually referred to as the cytochrome b /f complex, or plastoquinolplastocyanin oxidoreductase, which oxidizes plastoquinol reduced in PSII and reduces plastocyanin oxidized in PSI (25,41). Some diphenyl ethers, eg, 2,4-dinitrophenyl 2 -iodo-3 -methyl-4 -nitro-6 -isopropylphenyl ether [69311-70-2] (DNP-INT), and the quinone analogues,... [Pg.40]

The PSII complex contains two distinct plastoquiaones that act ia series. The first is the mentioned above the second, Qg, is reversibly associated with a 30—34 kDa polypeptide ia the PSII cote. This secondary quiaone acceptor polypeptide is the most rapidly tumed-over proteia ia thylakoid membranes (41,46). It serves as a two-electron gate and connects the single-electron transfer events of the reaction center with the pool of free... [Pg.42]

See other pages where Electron membrane is mentioned: [Pg.179]    [Pg.109]    [Pg.274]    [Pg.2]    [Pg.125]    [Pg.10]    [Pg.179]    [Pg.109]    [Pg.274]    [Pg.2]    [Pg.125]    [Pg.10]    [Pg.90]    [Pg.1647]    [Pg.1709]    [Pg.2502]    [Pg.2806]    [Pg.2817]    [Pg.2938]    [Pg.507]    [Pg.532]    [Pg.341]    [Pg.134]    [Pg.207]    [Pg.484]    [Pg.269]    [Pg.385]    [Pg.39]    [Pg.40]    [Pg.40]    [Pg.40]    [Pg.43]   
See also in sourсe #XX -- [ Pg.126 , Pg.141 , Pg.142 , Pg.149 , Pg.153 ]



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Biological membranes, electronic properties

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Composition of Thylakoid Membranes Lipids, Proteins, and Electron Carriers

Electron Transfer Along Bridging Molecules, Molecular Wires and Semiconductor Particles Embedded in Membranes

Electron Transport Creates an Electrochemical Potential Gradient for Protons across the Inner Membrane

Electron Tunneling Across the Membrane Core

Electron bilayer membranes

Electron conductor membranes

Electron micrograph cell membrane, figure

Electron micrograph membrane

Electron microscopic studies membranes

Electron microscopy of membranes

Electron spin resonance membranes

Electron transport chain, membrane-bound

Electron transport chain, membrane-bound enzymes

Electron transport in membranes

Electron transport system, thylakoid membrane

Electron-transfer Reactions in Vesicles and Membranes

Electronic Conduction in Liquid Crystalline Membranes Role of Unsaturated Lipids

Electronic devices, membranes applications

Electronic membrane osmometer

Electronic processes, bilayer lipid membranes

Electrons, and Protons in Cell Membranes

Fate of Electron Excitation Inside Membranes

Freeze-Fracture Electron Microscopy of Thylakoid Membranes

Hypotheses on the Mechanism of Electron Motion in Biological Membranes

Mechanisms of Electron Transfer Across Membranes

Membrane electron microscopy

Membrane lipids electron spin resonance

Membrane processes electron transfer

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Membrane, artificial electron micrographs

Membranes for Electronics

Membranes scanning electron microscopy/energy dispersive

Membranes, bilayer, photosensitized electron transfer

Mixed ionic and electronic conducting membrane

Mixed ionic and electronic conductivity MIEC) membranes

Mixed ionic and electronic conductivity membranes

Mixed ions-electrons conducting membranes

Mixed protonic-electronic conducting membrane

Mixed protonic-electronic conducting perovskite membrane

Mixed protonic-electronic membrane

Photoinduced Electron Transfer Membranes

Polymeric membranes electron microscopy

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Thylakoid membrane, electron transport

Transmission electron membranes

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