Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Electro formation

The silver-silver chloride electrode (Ag AgCl) is easily and cheaply made. Two silver electrodes are cleaned (see Section 9.1.1 above) and immersed in aqueous KCl solution (a concentration of 0.1 mol dm is convenient). Next, a potential of about 2 V is applied across them for c. 10 min, causing a thin outer film of silver chloride to develop on the positive electrode. Solid AgCl is formed by a two-step reaction, involving first the electro-formation of silver ion ... [Pg.284]

Angelova, M. I. and Dimitrov, D. S. (1988). A mechanism of liposome electro-formation. Progr. Colloid Polymer. ScL, 76, 59-67. [Pg.271]

In electro formation, a metal is electrodeposited in the shape and form of the desired object on top of a substrate (the mould) that is afterwards removed. An example is the manufacture of foils for electrical shavers the mould (cathode) is a cylinder with a design containing insulated parts where there is no electrodeposition and that turns slowly the anode is also cylindrical and concentric with the cathode, and the foil is separated from the mould with a knife (Fig. 15.8). The most commonly used metals... [Pg.345]

These questions also have a chemical component it would be helpful to understand the relationship between the chemical structure of the monomeric surfactant and the propensity to assemble to giant vesicles. It has been observed that, generally, a small amount of giant vesicles accompanies the formation of normal vesicles. However, this tendency varies strongly from surfactant to surfactant. This situation also occurs in the case of electroformation [2] some surfactants (e.g. fatty acids/soaps, phosphatidyl nucleosides) fail to give giant vesicles by the electro-formation method [3], and in fact the method seems to be restricted to phosphatidylcholine or to lipid mixtures containing phosphatidylcholine. It is fair to say that the relationship between the chemical structure and the propensity to form vesicles is still poorly understood. [Pg.8]

Electrophoresis and electro osmosis can be used to enhance conventional cake filtration. Electrodes of suitable polarity are placed on either side of the filter medium so that the incoming particles move toward the upstream electrode, away from the medium. As most particles carry negative charge, the electrode upstream of the medium is usuaHy positive. The electric field can cause the suspended particles to form a more open cake or, in the extreme, to prevent cake formation altogether by keeping aH particles away from the medium. [Pg.390]

Ion implantation (qv) has a large (10 K/s) effective quench rate (64). This surface treatment technique allows a wide variety of atomic species to be introduced into the surface. Sputtering and evaporation methods are other very slow approaches to making amorphous films, atom by atom. The processes involve deposition of a vapor onto a cold substrate. The buildup rate (20 p.m/h) is also sensitive to deposition conditions, including the presence of impurity atoms which can faciUtate the formation of an amorphous stmcture. An approach used for metal—metalloid amorphous alloys is chemical deposition and electro deposition. [Pg.337]

Cholesterol The end point for the cholesterol reaction can be determined by following dye formation. Additionally, the amount of oxygen consumed can be measured amperometricaHy by an oxygen-sensing electrode (see Electro analytical techniques). The H2O2 produced by cholesterol oxidase requires phenol to produce dye. [Pg.39]

ANALYSIS OF THE SIGNAL FORMATION IN DOUBLE STAGE ELECTRO-THERMAL ATOMIZER FOR ATOMIC ABSORPTION ANALYSIS... [Pg.84]

The process of signal formation in the double stage electro thermal atomizers for atomic absorption analysis significantly differs from the signal formation in the classic electro thermal atomizer. As this process determines efficiency of the application of the method it is necessary to have the understanding of the details of that process and the effect of the design pai ameters of the atomizer on the efficiency of analysis. [Pg.84]

In classic electro-thermal atomizer the process of formation of the analytical signal is combination of two processes the analyte supply (in the process of evaporation) and the analyte removal (by diffusion of the analyte from the atomizer). In double stage atomizer a very significant role plays the process of conductive transfer of the analyte form the evaporator to the atomizer itself and this makes the main and a principle difference of these devices. Additionally to the named difference arises the problem with optimization of the double stage atomizer as the amount of design pai ameters and possible combination of operation pai ameters significantly increases. [Pg.84]

The transfer of an element from the metal to the slag phase is one in which the species goes from the charge-neutralized metallic phase to an essentially ionic medium in the slag. It follows that there must be some electron redistribution accompanying the transfer in order that electro-neutrality is maintained. A metallic atom which is transfened must be accompanied by an oxygen atom which will absorb the elecuons released in the formation of tire metal ion, thus... [Pg.327]

Electro-conductivity of molten salts is a kinetic property that depends on the nature of the mobile ions and ionic interactions. The interaction that leads to the formation of complex ions has a varying influence on the electroconductivity of the melts, depending on the nature of the initial components. When the initial components are purely ionic, forming of complexes leads to a decrease in conductivity, whereas associated initial compounds result in an increase in conductivity compared to the behavior of an ideal system. Since electro-conductivity is never an additive property, the calculation of the conductivity for an ideal system is performed using the well-known equation proposed by Markov and Shumina (Markov s Equation) [315]. [Pg.149]

The extent of the irreversible charge losses due to film formation depends to a first approximation on the surface area of the lithiated carbon which is wetted by the electrolyte [36, 66, 120-124]. Electrode manufacturing parameters influencing the pore size distribution within the electrode [36, 121, 124, 125] and the coverage of the individual particles by a binder [124, 126] have an additional influence on the carbon electrode surface exposed to the electro-... [Pg.393]

The superior donor properties of amino groups over alkoxy substituents causes a higher electron density at the metal centre resulting in an increased M-CO bond strength in aminocarbene complexes. Therefore, the primary decarbo-nylation step requires harsher conditions moreover, the CO insertion generating the ketene intermediate cannot compete successfully with a direct electro-cyclisation of the alkyne insertion product, as shown in Scheme 9 for the formation of indenes. Due to that experience amino(aryl)carbene complexes are prone to undergo cyclopentannulation. If, however, the donor capacity of the aminocarbene ligand is reduced by N-acylation, benzannulation becomes feasible [22]. [Pg.131]

Figure 17. Energy for the nucleation of a surface film on metal electrode. M, metal OX, oxide film EL, electrolyte solution. Aj is the activation barrier for the formation of an oxide-film nucleus and rj is its critical radius. 7 a is the interfacial tension of the metal-electrolyte interface, a is the interfacial tension of the film-electrolyte interface. (From N. Sato, J. Electro-chem. Soc. 129, 255, 1982, Fig. 5. Reproduced by permission of The Electrochemical Society, Inc.)... Figure 17. Energy for the nucleation of a surface film on metal electrode. M, metal OX, oxide film EL, electrolyte solution. Aj is the activation barrier for the formation of an oxide-film nucleus and rj is its critical radius. 7 a is the interfacial tension of the metal-electrolyte interface, a is the interfacial tension of the film-electrolyte interface. (From N. Sato, J. Electro-chem. Soc. 129, 255, 1982, Fig. 5. Reproduced by permission of The Electrochemical Society, Inc.)...
There is no fundamental theory for electro-crystallization, owing in part to the complexity of the process of lattice formation in the presence of solvent, srrrfactants, and ionic solutes. Investigations at the atomic level in parallel with smdies on nonelectrochemical crystallization wotrld be rewarding and may lead to a theory for predicting the evolution of metal morphologies, which range from dertse deposits to crystalline particles and powders. [Pg.173]

The overheating effect is believed to play a dominant role in explaining the physical mechanism of the microbubble formation, and three main reasons could be underpinned First, it was observed that a small amount of the glycerin injected into the gap would eventually disappear after a few hours at the positive EEF intensity of 1 MV/cm. Second, no remarkable difference in the chemical composition between the glycerin before and after the EEF was applied could be found in the experiment, which indicated physical effects might predominate. Besides, a rough estimation of the temperature rise in the contact region due to the electro-thermal effect will be conducted as follows. [Pg.58]

Further convincing evidence was found by Catherino - for the formation of arsenic(IV) during the electro-oxidation of arsenic(III) in perchloric acid solution. [Pg.550]

Yamamoto and co-workers reported abase- and ligand-free palladium (II) catalysed method, in methanol at room temperature and under air [49], While the conversion of arylboronic acids bearing an electro-donating group was very efficient, the presence of an electro-withdrawing substituent led to lower conversions. To solve this problem and also prevent the fast formation of palladium black, Yamamoto and co-workers described a new approach where the reaction was catalysed by NHC-bearing complexes 21 and 22 in the presence of an oxidant (Fig. 7.4) [50]. The best results were obtained when complex 21b was used in methanol at room temperature, in the presence of a small excess of p-benzoquinone. [Pg.199]

Further studies were carried out on the Pd/Mo(l 1 0), Pd/Ru(0001), and Cu/Mo(l 10) systems. The shifts in core-level binding energies indicate that adatoms in a monolayer of Cu or Pd are electronically perturbed with respect to surface atoms of Cu(lOO) or Pd(lOO). By comparing these results with those previously presented in the literature for adlayers of Pd or Cu, a simple theory is developed that explains the nature of electron donor-electron acceptor interactions in metal overlayer formation of surface metal-metal bonds leads to a gain in electrons by the element initially having the larger fraction of empty states in its valence band. This behavior indicates that the electro-negativities of the surface atoms are substantially different from those of the bulk [65]. [Pg.85]

Weaver and co-workers have carried out extensive smdies of CO electro-oxidation on Au single crystals [Chang et al., 1991 Edens et al., 1996]. Continuous oxidation of CO on Au starts at potentials where the formation of surface oxides or surface-bonded hydroxyl (OH) is not apparent from voltammetry. Weaver suggested the following mechanism ... [Pg.175]


See other pages where Electro formation is mentioned: [Pg.384]    [Pg.100]    [Pg.259]    [Pg.490]    [Pg.527]    [Pg.483]    [Pg.494]    [Pg.493]    [Pg.196]    [Pg.220]    [Pg.800]    [Pg.2]    [Pg.54]    [Pg.332]    [Pg.305]    [Pg.864]    [Pg.237]    [Pg.237]    [Pg.235]    [Pg.417]    [Pg.58]    [Pg.145]    [Pg.603]    [Pg.609]    [Pg.154]    [Pg.322]    [Pg.148]   
See also in sourсe #XX -- [ Pg.139 ]




SEARCH



© 2024 chempedia.info