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Electrolyte motion

Oxygen may occur at low chloride concentrations, at low temperature or in the case of insufficient electrolyte motion. [Pg.180]

Numerous electrochemical reactor designs have been described in the literature for the removal and recovery of a range of dissolved metals from both synthetic and industrial process streams. Many of these have been developed into successful pilot- and full scale devices as indicated in this paper. In addition to the choice of reactor design (which includes decisions regarding electrode geometry and electrode/electrolyte motion), the following operational factors are seen to be important ... [Pg.38]

Hydrophilic polymers contain a commensurate amount of hydrophilic and hydrophobic fragments in macromolecular composition, including proteins, some polyurethanes and acrylate copolymers. Water is a good solvent for hydrophilic polymers, and therefore it often violates the original structure of the polymer on sorption of aqua solutions. Non-polar fragments, due to their macromolecular flexibility on sorption of aqua solutions, can associate and form areas of elevated hydrophoby to hamper the electrolyte motion. Hydrophilic sections of the chain encircled by the solvent are responsible for the electrolyte transfer. The majority of polymers cannot form fully hydrophobic areas because their polar and non-polar sections in macromolecules are frequently var3ung. [Pg.23]

Consider the electrolyte hydrodynamic flow condition shown in Figure 7.17. This is amass transfer found in electrowinning and electrorefining cells, in which the electrolyte motion is upwards on the anode surface due to the generation of oxygen bubbles, which enhances the mass transfer. The reader can observe in this model that the electrolyte motion is more intense at the top than at the bottom of the electrode as indicated by the arrows. If the current flows, then the electrolyte motion increases and descends to the bottom of the cathode. This is the case in which a significant convective molar flux is superimposed on the Pick s diffusion molar flux. The concentration gradient in the fluid adjacent to the vertical electrode (plate) surface causes a variation in the fluid density and the boundary layer (tf ) develops upwards from laminar to turbulent conditions [2,7]. [Pg.223]

Transference numbers are defined as ratio of ion motion to electrolyte motion. One possibility to calculate the transference number of a cation is the quotient of diffusion coefficient of the cation divided by difiusion coefficient of cation plus diffusion coefficient of anion ... [Pg.605]

The electrochemical seismometers offer an alternative to regular electromechanical devices. They are compact, robust, and easy to install and provide good quality data. The operation principles of the electrochemical seismometers are based on using the charge transfer variations due to electrolyte motion in the four-electrode... [Pg.960]

A finite time is required to reestabUsh the ion atmosphere at any new location. Thus the ion atmosphere produces a drag on the ions in motion and restricts their freedom of movement. This is termed a relaxation effect. When a negative ion moves under the influence of an electric field, it travels against the flow of positive ions and solvent moving in the opposite direction. This is termed an electrophoretic effect. The Debye-Huckel theory combines both effects to calculate the behavior of electrolytes. The theory predicts the behavior of dilute (<0.05 molal) solutions but does not portray accurately the behavior of concentrated solutions found in practical batteries. [Pg.509]

Ions of an electrolyte are free to move about in solution by Brownian motion and, depending on the charge, have specific direction of motion under the influence of an external electric field. The movement of the ions under the influence of an electric field is responsible for the current flow through the electrolyte. The velocity of migration of an ion is given by ... [Pg.509]

Complete and Incomplete Ionic Dissociation. Brownian Motion in Liquids. The Mechanism of Electrical Conduction. Electrolytic Conduction. The Structure of Ice and Water. The Mutual Potential Energy of Dipoles. Substitutional and Interstitial Solutions. Diffusion in Liquids. [Pg.38]

The Mechanism of Electrical Conduction. Let us first give some description of electrical conduction in terms of this random motion that must exist in the absence of an electric field. Since in electrolytic conduction the drift of ions of either sign is quite similar to the drift of electrons in metallic conduction, we may first briefly discuss the latter, where we have to deal with only one species of moving particle. Consider, for example, a metallic bar whose cross section is 1 cm2, and along which a small steady uniform electric current is flowing, because of the presence of a weak electric field along the axis of the bar. Let the bar be vertical and in Fig. 16 let AB represent any plane perpendicular to the axis of the bar, that is to say, perpendicular to the direction of the cuirent. [Pg.42]

Figure 4. Two representations (on the left) of cation motion in a polymer electrolyte assisted by polymer chain motion only, and two (on the right) showing cation motion taking account of ionic cluster contributions. Figure 4. Two representations (on the left) of cation motion in a polymer electrolyte assisted by polymer chain motion only, and two (on the right) showing cation motion taking account of ionic cluster contributions.
T0 is a reference temperature which can be identified with T, and although the constant B is not related to any simple activation process, it has dimensions of energy. This form of the equation is derived by assuming an electrolyte to be fully dissociated in the solvent, so it can be related to the diffusion coefficient through the Stokes-Einstein equation. It suggests that thermal motion above T0 contributes to relaxation and transport processes and that... [Pg.507]

Ionic transport in solid electrolytes and electrodes may also be treated by the statistical process of successive jumps between the various accessible sites of the lattice. For random motion in a three-dimensional isotropic crystal, the diffusivity is related to the jump distance r and the jump frequency v by [3] ... [Pg.532]

Though solid electrolytes for multivalent ions offer the advantage of a larger charge transfer, their conductivities are much lower than those of monovalent ions at ambient temperature because of a higher activation enthalpy for the ionic motion... [Pg.533]

Chemically active plastics such as the polyelectrolytes have been used to make artificial muscle materials. This is an unusual type of mechanical power device that creates motion by the lengthening and shortening of fibers made from a chemically active plastic by changing the composition of the surrounding liquid medium, either directly or by the use of electrolytic chemical action. Obviously this form of mechanical power generation is no competitor to thermal energy sources, but it is potentially valuable in detector equipment that would be sensitive to the changing... [Pg.260]

When these drugs are given to the female patient with inoperable breast carcinoma, tire nurse evaluates the patient s current status (physical, emotional, and nutritional) carefully and records tire finding in tire patient s chart. Problem areas, such as pain, any limitation of motion, and the ability to participate in tire activities of daily living, are carefully evaluated and recorded in tiie patient s record. The nurse takes and records vital signs and weight. Baseline laboratory tests may include a complete blood count, hepatic function tests, serum electrolytes, and serum and urinary calcium levels. The nurse reviews these tests and notes any abnormalities. [Pg.541]

The classical example of a soUd organic polymer electrolyte and the first one found is the poly(ethylene oxide) (PEO)/salt system [593]. It has been studied extensively as an ionically conducting material and the PEO/hthium salt complexes are considered as reference polymer electrolytes. However, their ambient temperature ionic conductivity is poor, on the order of 10 S cm, due to the presence of crystalUne domains in the polymer which, by restricting polymer chain motions, inhibit the transport of ions. Consequently, they must be heated above about 80 °C to obtain isotropic molten polymers and a significant increase in ionic conductivity. [Pg.202]

Electric currents in electrolyte solutions are the directed motions of ions under the influence of an applied electric field. Ions in solution are in a state of continuous kinetic molecular (thermal) motion. This motion is chaotic when an electrostatic field is not present (i.e., the ions do not move preferentially in any particular direction, and there is no current flow). [Pg.9]

In electrolyte solutions the positively and negatively charged ions will move in opposite directions when an electric field is applied. Therefore, outwardly the effect of motion of positive ions is exactly the same as that of the motion of negative ions, and the total current density is the sum of the partial currents due to hansport of each type of ion ... [Pg.10]

See other pages where Electrolyte motion is mentioned: [Pg.60]    [Pg.65]    [Pg.530]    [Pg.196]    [Pg.527]    [Pg.1]    [Pg.229]    [Pg.60]    [Pg.65]    [Pg.530]    [Pg.196]    [Pg.527]    [Pg.1]    [Pg.229]    [Pg.584]    [Pg.2676]    [Pg.203]    [Pg.387]    [Pg.306]    [Pg.510]    [Pg.539]    [Pg.503]    [Pg.507]    [Pg.508]    [Pg.509]    [Pg.512]    [Pg.514]    [Pg.514]    [Pg.518]    [Pg.606]    [Pg.611]    [Pg.92]    [Pg.271]    [Pg.102]    [Pg.184]    [Pg.643]    [Pg.645]   
See also in sourсe #XX -- [ Pg.2 ]



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Ionic motion, polymer electrolytes

Motion of electrolyte

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