Isentropic relations

First law of thermodynamics:

d e = δ q - δ w

(Eq. 1.10)

For a reversible process: $δ w = p d (1 / ρ)$ and $δ q = T d s$

d e = T d s - p d (\frac{1}{ρ})

(Eq. 1.11)

Enthalpy is defined as: $h = e + p / ρ$ and thus

d h = d e + p d (\frac{1}{ρ}) + (\frac{1}{ρ}) d p

(Eq. 1.12)

Eliminate $d e$ in (Eq. 1.11) using (Eq. 1.12)

T d s = d h - p d (\frac{1}{ρ}) - (\frac{1}{ρ}) d p + p d (\frac{1}{ρ})

(Eq. 1.13)

d s = \frac{d h}{T} - \frac{d p}{ρ T}

(Eq. 1.14)

Using $d h = C_{p} T$ and the equation of state $p = ρ R T$ , we get

d s = C_{p} \frac{d T}{T} - R \frac{d p}{p}

(Eq. 1.15)

Integrating (Eq. 1.15) gives

s_{2} - s_{1} = \int_{1}^{2} C_{p} \frac{d T}{T} - R \ln (\frac{p_{2}}{p_{1}})

(Eq. 1.16)

For a calorically perfect gas, $C_{p}$ is constant (not a function of temperature) and can be moved out from the integral and thus

s_{2} - s_{1} = C_{p} \ln (\frac{T_{2}}{T_{1}}) - R \ln (\frac{p_{2}}{p_{1}})

(Eq. 1.17)

An alternative form of (Eq. 1.17) is obtained by using $d e = C_{v} d T$ in (Eq. 1.11), which gives

s_{2} - s_{1} = \int_{1}^{2} C_{v} \frac{d T}{T} - R \ln (\frac{ρ_{2}}{ρ_{1}})

(Eq. 1.18)

Again, for a calorically perfect gas, we get

s_{2} - s_{1} = C_{v} \ln (\frac{T_{2}}{T_{1}}) - R \ln (\frac{ρ_{2}}{ρ_{1}})

(Eq. 1.19)

Adiabatic and reversible processes, i.e., isentropic processes implies $d s = 0$ and thus (Eq. 1.17) reduces to

\frac{C_{p}}{R} \ln (\frac{T_{2}}{T_{1}}) = \ln (\frac{p_{2}}{p_{1}})

(Eq. 1.20)

$\frac{C_{p}}{R} = \frac{γ}{γ - 1}$

$\frac{γ}{γ - 1} \ln (\frac{T_{2}}{T_{1}}) = \ln (\frac{p_{2}}{p_{1}}) \Rightarrow$

\frac{p_{2}}{p_{1}} = {(\frac{T_{2}}{T_{1}})}^{γ / (γ - 1)}

(Eq. 1.21)

In the same way, (Eq. 1.19) gives

\frac{ρ_{2}}{ρ_{1}} = {(\frac{T_{2}}{T_{1}})}^{1 / (γ - 1)}

(Eq. 1.22)

Eqn. (Eq. 1.21) and Eqn. (Eq. 1.22) constitutes the isentropic relations

\frac{p_{2}}{p_{1}} = {(\frac{ρ_{2}}{ρ_{1}})}^{γ} = {(\frac{T_{2}}{T_{1}})}^{γ / (γ - 1)}

(Eq. 1.23)

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