This question is incomplete, the complete question is;
The entropy of an ?-ideal gas changes in the following way as a function of temperature and volume:
ĪS = nRln(V[tex]_f[/tex]/V[tex]_i[/tex]) + ānRln(T[tex]_f[/tex]/T[tex]_i[/tex])
For an adiabatic process, the change in T is determined by the change in V. In this problem you will compute the contributions to S from the V and T terms separately, then add them up to find the total entropy change for an adiabatic process.
Argon gas, initially at pressure 100 kPa and temperature 300 K, is allowed to expand adiabatically from 0.01 mĀ³ to 0.026 mĀ³ while doing work on a piston.
1) What is the change in entropy due to the volume change alone, ignoring any effects of changing internal energy? ĪS = ? J/K
2) For this adiabatic expansion, what is the final temperature? Ā T[tex]_f[/tex] = Ā ? K
Answer:
1) the change in entropy due to the volume change alone, ignoring any effects of changing internal energy is 3.185 J/K.
2) the final temperature is 158.66 K
Explanation:
Given the data in the question;
ĪS = nRln(V[tex]_f[/tex]/V[tex]_i[/tex]) + ānRln(T[tex]_f[/tex]/T[tex]_i[/tex])
P[tex]_i[/tex] = 100 kPa = 100000 Pa
V[tex]_i[/tex] = 0.01 mĀ³
V[tex]_f[/tex] = 0.026 mĀ³
T[tex]_i[/tex] = 300 K
1) Ā the change in entropy due to the volume change alone
from the question; ĪS = nRln(V[tex]_f[/tex]/V[tex]_i[/tex]) + ānRln(T[tex]_f[/tex]/T[tex]_i[/tex])
so change in entropy due to the volume change alone is;
ĪS = nRln(V[tex]_f[/tex]/V[tex]_i[/tex])
we know that, from ideal gas law; PV = nRT
so, nR = P[tex]_i[/tex]V[tex]_i[/tex]/T[tex]_i[/tex] Ā ---- let this be equation 1
ā“ ĪS = P[tex]_i[/tex]V[tex]_i[/tex]/T[tex]_i[/tex] Ć ln(V[tex]_f[/tex]/V[tex]_i[/tex])
we substitute
ĪS = [( 100000 Pa Ć Ā 0.01 mĀ³) / 300 K ] Ć ln(0.026mĀ³ / 0.01mĀ³ )
ĪS = 3.185 J/K Ā
Therefore, the change in entropy due to the volume change alone, ignoring any effects of changing internal energy is 3.185 J/K.
2) Ā Final temperature
we know that, in an adiabatic expansion;
[tex]PV^Y[/tex] = K
where Y = 5/3
so
[tex]P_i[/tex][tex]V_i^{(5/3)[/tex] = [tex]P_f[/tex][tex]V_f^{(5/3)[/tex]
[tex]P_f[/tex] = [tex]P_i[/tex][tex]( \frac{V_i}{V_f})^{(5/3)[/tex]
we substitute
[tex]P_f[/tex] = ( 100000 Pa) [tex]( \frac{0.01 m^3}{0.026 m^3})^{(5/3)[/tex]
[tex]P_f[/tex] = 20341.255 Pa
Also from ideal gas law;
PV = nRT
T = PV / nR
so
T[tex]_f[/tex] = P[tex]_f[/tex]V[tex]_f[/tex] / nR
but from equation 1; nR = PV/T
so
T[tex]_f[/tex] = (P[tex]_f[/tex]V[tex]_f[/tex]) / (P[tex]_i[/tex]V[tex]_i[/tex]/T[tex]_i[/tex] )
T[tex]_f[/tex] = ( P[tex]_f[/tex]V[tex]_f[/tex]T[tex]_i[/tex] / P[tex]_i[/tex]V[tex]_i[/tex] )
we substitute
T[tex]_f[/tex] = ( 20341.255 Pa Ć 0.026 mĀ³ Ć Ā 300 K) / 100000 Pa Ć 0.01 mĀ³ )
T[tex]_f[/tex] = 158.66 K
Therefore, the final temperature is 158.66 K
