Equilibria chemical potential

Chemical Potential. Equilibrium calculations are based on the equaHty of individual chemical potentials (and fiigacities) between phases in contact (10). In gas—soHd adsorption, the equiHbrium state can be defined in terms of an adsorption potential, which is an extension of the chemical potential concept to pore-filling (physisorption) onto microporous soHds (11—16). 

Concepts Spontaneous chemical reactions The use of thermodynamics to determine what reactions are possible in a particular prebiotic environment, including the ideas of chemical potential, equilibrium and extent of reaction... 

See Activity Coefficients Additivity Principle Biochemical Thermodynamics Chemical Potential Equilibrium Constants Hess s Law Innate Thermodynamic Quantities Molecular Crowding Thermodynamics, Laws of Thermodynamic Cycle Thermodynamic Equations of State... 

ACTIVITY COEEEICIENTS ADDITIVITY PRINCIPLE BIOCHEMICAL THERMODYNAMICS CHEMICAL POTENTIAL EQUILIBRIUM CONSTANTS HESS S LAW... 

Fig. 3.15 Energy diagram of semiconductor-metal photoelectrolysis cell, (a) No contact and no chemical potential equilibrium (b) galvanic contact in dark (c) effect of light illumination (d) effect of light illumination with bias, (e) Light illumination without bias, however in this case the semiconductor band edges straddle the redox potential for water photoelectrolysis.

Substitute chemical potential equilibrium relations into the potential definition. 

The establishment of chemical potential equilibrium (with respect to either a setpoint or phase coexistence) is the central component of most Monte Carlo schemes for simulation of the phase behavior and stability of molecular systems. Simulation of the chemical potential (or chemical potential equilibration) in a polymeric system requires more effort than the corresponding calculation for a simple fluid. The reason is that efficient conformational sampling of the polymer is implicitly required for a free-energy calculation and, in fact, the ergodicity problems described in earlier sections are often exacerbated. 

Equilibrium conditions can be conveniently subdivided into thermal, mechanical, and chemical potential equilibrium. In thermal equilibrium, heat transfer stops and the temperatures of the two phases are equal. 

The relation between osmotic presstne and solvent activity is to be found from the chemical potential equilibrium condition, taking into account the pressure dependence of t]. From the rules of phenomenological thermodynamics, one obtains ... 

The thermodynamics of dissolution of the oxygenates from gasoline LNAPL is defined using chemical potential. Equilibrium occurs when the chemical potentials in each phase are equal [8] ... 

PRINCIPLE AIM-HDl (of Le Chatelier-Braun) A primary change of the charges number of an atom A in a molecule, say dN, induces a (secondary) redistribution SN of the charges number between the atoms from the rest of the molecule, in order to decrease the primary hardness which produced the change in the atom A charge. The chemical potentials equilibrium and of chemical hardness in molecule will be ultimately accomplished by a readjustment of the net charges between the atoms (molecular fragments) involved in the primary and secondary processes. 

Let us now consider the changes of the bulk-phase energies caused by partial evaporation of the drop. At constant temperature and chemical potentials, equilibrium is determined by a minimum of the grand potential ... 

In thermodynamic terms the equilibrium constant is related to the standard chemical potential by the equation... 

In an irreversible process the temperature and pressure of the system (and other properties such as the chemical potentials to be defined later) are not necessarily definable at some intemiediate time between the equilibrium initial state and the equilibrium final state they may vary greatly from one point to another. One can usually define T and p for each small volume element. (These volume elements must not be too small e.g. for gases, it is impossible to define T, p, S, etc for volume elements smaller than the cube of the mean free... 

Here p is the chemical potential just as the pressure is a mechanical potential and the temperature Jis a thennal potential. A difference in chemical potential Ap is a driving force that results in the transfer of molecules tlnough a penneable wall, just as a pressure difference Ap results in a change in position of a movable wall and a temperaPire difference AT produces a transfer of energy in the fonn of heat across a diathennic wall. Similarly equilibrium between two systems separated by a penneable wall must require equality of tire chemical potential on the two sides. For a multicomponent system, the obvious extension of equation (A2.1.22) can be written... 

If there are more than two subsystems in equilibrium in the large isolated system, the transfers of S, V and n. between any pair can be chosen arbitrarily so it follows that at equilibrium all the subsystems must have the same temperature, pressure and chemical potentials. The subsystems can be chosen as very small volume elements, so it is evident that the criterion of internal equilibrium within a system (asserted earlier, but without proof) is unifonnity of temperature, pressure and chemical potentials tlu-oughout. It has now been... 

It follows that, because phase equilibrium requires that the chemical potential p. be the same in the solution as in the gas phase, one may write for the chemical potential in the solution ... 

Instead of using the chemical potential p. one can use the absolute activity X. = exp( xJRT). Since at equilibrium A= 0,... 

To proceed fiirther, to evaluate the standard free energy AG , we need infonnation (experimental or theoretical) about the particular reaction. One source of infonnation is the equilibrium constant for a chemical reaction involving gases. Previous sections have shown how the chemical potential for a species in a gaseous mixture or in a dilute solution (and the corresponding activities) can be defined and measured. Thus, if one can detennine (by some kind of analysis)... 

In these equations the electrostatic potential i might be thought to be the potential at the actual electrodes, the platinum on the left and the silver on the right. However, electrons are not the hypothetical test particles of physics, and the electrostatic potential difference at a junction between two metals is nnmeasurable. Wliat is measurable is the difference in the electrochemical potential p of the electron, which at equilibrium must be the same in any two wires that are in electrical contact. One assumes that the electrochemical potential can be written as the combination of two tenns, a chemical potential minus the electrical potential (- / because of the negative charge on the electron). Wlien two copper wires are connected to the two electrodes, the... 

Fluctuations of observables from their average values, unless the observables are constants of motion, are especially important, since they are related to the response fiinctions of the system. For example, the constant volume specific heat of a fluid is a response function related to the fluctuations in the energy of a system at constant N, V and T, where A is the number of particles in a volume V at temperature T. Similarly, fluctuations in the number density (p = N/V) of an open system at constant p, V and T, where p is the chemical potential, are related to the isothemial compressibility iCp which is another response fiinction. Temperature-dependent fluctuations characterize the dynamic equilibrium of themiodynamic systems, in contrast to the equilibrium of purely mechanical bodies in which fluctuations are absent. 

Assume diat die chemical potential, p., of surfactant in aggregates of size N in equilibrium widi one anodier is unifonii. One may dierefore write... 

At equilibrium, in order to achieve equality of chemical potentials, not only tire colloid but also tire polymer concentrations in tire different phases are different. We focus here on a theory tliat allows for tliis polymer partitioning [99]. Predictions for two polymer/colloid size ratios are shown in figure C2.6.10. A liquid phase is predicted to occur only when tire range of attractions is not too small compared to tire particle size, 5/a > 0.3. Under tliese conditions a phase behaviour is obtained tliat is similar to tliat of simple liquids, such as argon. Because of tire polymer partitioning, however, tliere is a tliree-phase triangle (ratlier tlian a triple point). For smaller polymer (narrower attractions), tire gas-liquid transition becomes metastable witli respect to tire fluid-crystal transition. These predictions were confinned experimentally [100]. The phase boundaries were predicted semi-quantitatively. 

The problem has been discussed in terms of chemical potential by Everett and Haynes, who emphasize that the condition of diffusional equilibrium throughout the adsorbed phase requires that the chemical potential shall be the same at all points within the phase and since, as already noted, the interaction energy varies wtih distance from the wall, the internal pressure must vary in sympathy, so as to enable the chemical potential to remain constant. 

Figure 3.10 is a plot of potential against distance from the wall for a liquid in a capillary of sufficient width for its middle A to be outside the range of forces from the wall. Since the capillary condensate is in equilibrium with the vapour, its chemical potential (=p represented by the horizontal line GF, will be lower than that of the free liquid the difference in chemical potential of the condensate at A, represented by the vertical distance AF, is brought about entirely by the pressure drop, Ap = 2y/r , across the meniscus (cf. Equation (3.6)) but at some point B. say, nearer the wall, the chemical potential receives a contribution represented by the line BC, from the adsorption potential. Consequently, the reduction Ap in pressure across the meniscus must be less at B than at A, so that again... 

Picture the transfer, under equilibrium conditions, of dn mole of adsorptive from the bulk liquid where its chemical potential is /i , to a... 

The criterion for phase equilibrium is given by Eq. (8.14) to be the equality of chemical potential in the phases in question for each of the components in the mixture. In Sec. 8.8 we shall use this idea to discuss the osmotic pressure of a... 

Experimental results describing limited mutual solubility are usually presented as phase diagrams in which the compositions of the phases in equilibrium with each other at a given temperature are mapped for various temperatures. As noted above, the chemical potentials are the same in the equilibrium phases, so Eqs. (8.53) and (8.54) offer a method for calculating such... 

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