Page:Scientific Memoirs, Vol. 1 (1837).djvu/382

when the pressure is varied, enables us to calculate the value of the differential coefficient ${\displaystyle {\frac {d\,C}{d\,t}}}$.

In fact, according to our formulas, the specific caloric of the air under two pressures ${\displaystyle p}$ and ${\displaystyle p'}$ differs by ${\displaystyle R{\frac {d\,C}{d\,t}}-\log {\frac {p}{p'}}}$; rendering this quantity equal to the difference of the specific calorics, as it has been deduced from the results of MM. De Laroche and Bérard; taking the mean of two experiments, we find

${\displaystyle {\frac {d\,C}{d\,t}}=0.002565.}$

In these experiments the air entered into the calorimeter at the temperature of ${\displaystyle 96^{\circ }.90}$, and quitted it at that of ${\displaystyle 22^{\circ }.83}$; ${\displaystyle 0.002565}$ is therefore the mean value of the differential coefficient ${\displaystyle {\frac {d\,C}{d\,t}}}$ between these two temperatures.

From this result we learn, that between these two limits the function ${\displaystyle C}$ increases, though very slowly; consequently the quantity ${\displaystyle {\frac {1}{C}}}$ diminishes; whence it follows that the effect produced by the heat diminishes at high temperatures, though very slowly.

The theory of vapours will furnish us with new values of the function ${\displaystyle C}$ at other temperatures. Let us return to the formula

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

which we have demonstrated in paragraph IV. If we neglect the density of the vapour before that of the fluid, this formula will be reduced to

${\displaystyle {\frac {1}{C}}={\frac {\frac {d\,p}{d\,t}}{k}}.}$

We may remark in passing, that at the temperature of ebullition ${\displaystyle {\frac {d\,p}{d\,t}}}$ is nearly the same for all vapours; ${\displaystyle C}$ itself varies little with the temperature, so that ${\displaystyle k}$ is nearly constant. This explains the observations of certain philosophers, who have remarked that at the boiling point, equal volumes of all vapours contain the same quantity of latent caloric; but we see at the same time that we are only approximating to this law, since it supposes that ${\displaystyle C}$ and ${\displaystyle {\frac {d\,p}{d\,t}}}$ are the same for all vapours at the boiling point.