Specific heat: Difference between revisions

Latest revision as of 13:29, 30 March 2026

For thermally perfect and calorically perfect gases

\begin{matrix} C_{p} = \frac{d h}{d T} \\ C_{v} = \frac{d e}{d T} \end{matrix}

(Eq. 1.1)

From the definition of enthalpy and the equation of state $p = ρ R T$

h = e + \frac{p}{ρ} = e + R T

(Eq. 1.2)

Differentiate (Eq. 1.2) with respect to temperature gives

\frac{d h}{d T} = \frac{d e}{d T} + \frac{d (R T)}{d T}

(Eq. 1.3)

Inserting the specific heats gives

C_{p} = C_{v} + R

(Eq. 1.4)

Dividing (Eq. 1.4) by $C_{v}$ gives

\frac{C_{p}}{C_{v}} = 1 + \frac{R}{C_{v}}

(Eq. 1.5)

Introducing the ratio of specific heats defined as

γ = \frac{C_{p}}{C_{v}}

(Eq. 1.6)

Now, inserting (Eq. 1.6) in Eqn. \ref{eq:specificheat:c} gives

C_{v} = \frac{R}{γ - 1}

(Eq. 1.7)

In the same way, dividing (Eq. 1.4) with $C_{p}$ gives

1 = \frac{C_{v}}{C_{p}} + \frac{R}{C_{p}} = \frac{1}{γ} + \frac{R}{C_{p}}

(Eq. 1.8)

and thus

C_{p} = \frac{γ R}{γ - 1}

(Eq. 1.9)

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 For thermally perfect and calorically perfect gases