Page:Scientific Memoirs, Vol. 1 (1837).djvu/374

of the liquid corresponding to the temperature ${\displaystyle t}$ of the body ${\displaystyle A}$, and ${\displaystyle f\,g}$ that which corresponds to the temperature ${\displaystyle t-d\,t}$ of the body ${\displaystyle B}$; ${\displaystyle b\,h}$ the increase of volume due to the vapour formed in contact with the body ${\displaystyle A}$, ${\displaystyle h\,k}$ that which is due to the vapour formed after the body ${\displaystyle A}$ has been removed, the formation of which has reduced the temperature by the quantity ${\displaystyle d\,t}$; we have seen, I say, that the quantity of action developed by the transmission of the latent caloric furnished by the body ${\displaystyle A}$, [and transmitted] from that body to the body ${\displaystyle B}$, is measured by the quadrilateral figure ${\displaystyle c\,d\,e\,f}$. Now this surface is equal, if we neglect the infinitely small quantities of the second order, to the product of the volume ${\displaystyle c\,d}$ by the differential of the pressure ${\displaystyle d\,h-e\,k}$. Naming ${\displaystyle p}$ the pressure of the vapour of the liquid corresponding to the temperature ${\displaystyle t}$, ${\displaystyle p}$ will be a function of ${\displaystyle t}$, and we shall have ${\displaystyle d\,h-e\,k={\frac {d\,p}{d\,t}}d\,t}$.

${\displaystyle c\,d}$ will be equal to the increase of volume produced in water when it passes from the liquid into the gaseous state, under the pressure ${\displaystyle p}$, at a corresponding temperature. If we call ${\displaystyle \rho }$ the density of the liquid, ${\displaystyle \delta }$ that of the vapour, and ${\displaystyle v}$ the volume of the vapour formed, ${\displaystyle \delta v}$ will be its weight, and ${\displaystyle {\frac {\delta v}{\rho }}}$ will be the volume of the liquid evaporated. The increase of volume owing to the formation of a volume ${\displaystyle v}$ of vapour will therefore be

${\displaystyle v\left(1-{\frac {\delta }{\rho }}\right).}$

The effect produced will therefore be

${\displaystyle \left(1-{\frac {\delta }{\rho }}\right)v{\frac {d\,p}{d\,t}}d\,t.}$

The heat, by means of which this quantity of action has been produced, is the latent caloric of the volume ${\displaystyle v}$ of vapour formed; let ${\displaystyle k}$ be a function of ${\displaystyle t}$ representing the latent caloric contained in the unity of volume of the vapour furnished by the liquid subjected to experiment, at a temperature ${\displaystyle t}$, and under a corresponding pressure, the latent caloric of the volume ${\displaystyle v}$ will be ${\displaystyle kv}$, and the ratio of the effect produced to the heat expended will be expressed by

${\displaystyle {\frac {\left(1-{\frac {\delta }{\rho }}\right){\frac {d\,p}{d\,t}}d\,t}{k}}.}$

We have demonstrated that it is the greatest which can possibly be obtained; that it is independent of the nature of the liquid employed, and the same as that obtained by the employment of the permanent gases: now we have seen that this is expressed by ${\displaystyle {\frac {d\,t}{C}}}$, ${\displaystyle C}$ being a function of ${\displaystyle t}$ independent of the nature of the gases; we shall therefore also have