Page:Scientific Papers of Josiah Willard Gibbs.djvu/387

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In the same homogenous mass we may distinguish the potentials for an indefinite number of substances, each of which has a perfectly determined value. Between the potentials for different substances in the same homogeneous mass the same equations will subsist as between the units of these substances,		93
The values of potentials depend upon the arbitrary constants involved in the definition of the energy and entropy of each elementary substance,		95
coexistent phases.
Definition of phases—of coexistent phases,		96
Number of the independen variations which are possible in a system of coexistent phases,		96
Case of n+1 coexistent phases,		97
Cases of a less number of coexistent phases,		99
internal stability of homogeneous fluids as indicated by fundamental equations.
General condition of absolute stability,		100
Other forms of the condition,		104
Stability in respect to continuous changes of phase,		105
Conditions which characterize the limits of stability in this respect,		112
geometrical illustrations.
Surfaces in which the composition of the body represented is constant,		115
Surfaces and curves in which the composition of the body represented is variable and its temperature and pressure are constant,		118
critical phases.
Definition,		129
Number of independent variations which are possible for a critical phase while remaining such,		130
Analytical expression of the condition which characterize critical phases.—Situation of critical phases with respect to the limits of stability,		130
Variations which are possible under different circumstances in the condition of a mass initially in a critical phase,		132
on the values of the potentials when the quantity of one of the components is very small.		135
on certain points relating to the molecular constitution of bodies.
Proximate and ultimate components,		138
Phases of dissipated energy,		140
Catalysis,—perfect catalytic agent,		141
A fundamental equation for phases of dissipated energy may be formed from the more general form of the fundamental equation,		142
The phases of dissipated energy may sometimes be the only phases the existence of which can be experimentally verified,		142
the conditions of equilibrium for heterogeneous masses under the influence of gravity.
The problem is treated by two different methods:
The elements of volume are regarded as variable,		144
The elements of volume are regarded as fixed,		147
fundamental equations of ideal gases and gas-mixtures.
Ideal gas,		150
Ideal gas-mixture—Dalton's Law,		154
Inferences in regard to potentials in liquids and solids,		164
Considerations relating to the increase of entropy due to the mixture of gases by diffusion,		165