Page:Scientific Papers of Josiah Willard Gibbs.djvu/329

The condition of stability for the system when the pressures and tensions are regarded as constant, and the position of the surfaces ${\displaystyle {\text{A-B, B-C, C-A}}}$ as fixed, is that ${\displaystyle W_{S}-W_{V}}$ shall be a minimum under the same conditions. (See (549).) Now for any constant values of the tensions and of ${\displaystyle p_{A},p_{B},p_{C}}$, we may make ${\displaystyle v_{D}}$ so small that when it varies, the system remaining in equilibrium (which will in general require a variation of ${\displaystyle p_{D}}$), we may neglect the curvatures of the lines ${\displaystyle da,db,dc}$, and regard the figure ${\displaystyle abcd}$ as remaining similar to itself. For the total curvature (i.e., the curvature measured in degrees) of each of the lines ${\displaystyle ab,bc,ca}$ may be regarded as constant, being equal to the constant difference of the sum of the angles of one of the curvilinear triangles ${\displaystyle adb,bdc,cda}$ and two right angles. Therefore, when V D is very small, and the system is so deformed that equilibrium would be preserved if ${\displaystyle v_{D}}$ had the proper variation, but this pressure as well as the others and all the tensions remain constant, ${\displaystyle W_{S}}$ will vary as the lines in the figure ${\displaystyle abcd}$, and ${\displaystyle W_{V}}$ as the square of these lines. Therefore, for such deformations,

${\displaystyle W_{V}\propto W_{S}^{2}.}$

This shows that the system cannot be stable for constant pressures and tensions when ${\displaystyle W_{V}}$ is small and ${\displaystyle W_{V}}$ is positive, since ${\displaystyle W_{S}-W_{V}}$ will not be a minimum. It also shows that the system is stable when ${\displaystyle W_{V}}$ is negative. For, to determine whether ${\displaystyle W_{S}-W_{V}}$ is a minimum for constant values of the pressures and tensions, it will evidently be sufficient to consider such varied forms of the system as give the least value to ${\displaystyle W_{S}-W_{V}}$ for any value of ${\displaystyle v_{D}}$ in connection with the constant pressures and tensions. And it may easily be shown that such forms of the system are those which would preserve equilibrium if ${\displaystyle p_{D}}$ had the proper value.

These results will enable us to determine the most important questions relating to the stability of a line along which three homogeneous fluids ${\displaystyle A,B,C}$ meet, with respect to the formation of a different fluid ${\displaystyle D}$. The components of ${\displaystyle D}$ must of course be such as are found in the surrounding bodies. We shall regard ${\displaystyle p_{D}}$ and ${\displaystyle \sigma _{DA},\sigma _{DB},\sigma _{DC}}$ as determined by that phase of ${\displaystyle D}$ which satisfies the conditions of equilibrium with the other bodies relating to temperature and the potentials. These quantities are therefore determinable, by means of the fundamental equations of the mass ${\displaystyle D}$ and of the surfaces ${\displaystyle {\text{D-A, D-B, D-C}}}$, from the temperature and potentials of the given system.

Let us first consider the case in which the tensions, thus determined, can be represented as in figure 15, and ${\displaystyle p_{D}}$ has a value consistent with the equilibrium of a small mass such as we have been considering. It appears from the preceding discussion that