Title: Ch' 5 2nd Law of Thermodynamics
1Ch. 5 2nd Law of Thermodynamics
- 2nd Law Summary
- Entropy is defined as a state function and (as
internal energy) has an arbitrary additive
constant, but we are generally interested only in
changes in entropy. - Formulations (with always applying to
reversible) - Finite process
- Adiabatic process
- Isentropic process
- Finite isothermal process
- cycle
2Ch. 5 2nd Law of Thermodynamics
- 2nd Law Summary
- We also have
- Isochoric process
- Isobaric process
- Of course entropy can be related to the 1st Law
in general, by dividing by T, to get
3Ch. 5 2nd Law of Thermodynamics
- 2nd Law Summary
- We can also use the variables p and T using the
other form of the 1st Law to get a slightly less
useful expression, i.e., - These equalities apply to reversible processes.
4Ch. 5 2nd Law of Thermodynamics
- Entropy and the 1st Law
- If we write TdS ? ?Q we can include entropy in
the 1st Law, which will now be generalized for
reversible and irreversible processes (the ?
sign). - by virtue of the fact that dU CVdT. We can
rewrite this - Similarly
5Ch. 5 2nd Law of Thermodynamics
- Free Energy Functions
- In these two expressions, U and H appear as
functions of S and V, and S and p, respectively,
as independent variables. - It is often convenient to have general
expressions where pairs T, V and T, p appear as
independent variables. - This leads to the introduction of two new state
variables, the Helmholtz function (free energy)
and the Gibbs function (free energy/enthalpy).
They are defined as
6Ch. 5 2nd Law of Thermodynamics
- Free Energy Functions
- Both of these functions are sometimes referred to
as thermodynamic potentials. - We can then differentiate these expressions to
get relationships involving pairs T, V and T, p. - Which, using dU ? TdS pdV we get
7Ch. 5 2nd Law of Thermodynamics
- Free Energy Functions
- By the same procedure the Helmholtz function
becomes - leading to, (using dH ? TdS Vdp)
- Interpretation
- For isothermal process dF ? ??W and F is the
energy that can be converted to work - For isothermal-isobaric process (phase change) dG
0 so G is conserved
8Ch. 5 2nd Law of Thermodynamics
- Free Energy Functions
- The table below summarizes the characteristic
functions and their fundamental equations.
9Ch. 5 2nd Law of Thermodynamics
- State Functions
- Taking the characteristic functions in the table
and using the sign we can manipulate the 1st
and 2nd equations as - Similarly we get, through combining the other
pairs of equations (noting that these are true
regardless of whether the process is reversible
or irreversible).
10Ch. 5 2nd Law of Thermodynamics
- Maxwell Relations
- All the thermodynamic functions (U, H, S, F, G)
are State Functions (exact differentials) and are
subject to the mathematical characteristics we
discussed earlier. That is - Using this and the expressions derived on the
previous slide we can get the so-called Maxwell
equations - Start with the 1st equation
- And substitute for T and p from the previous slide
11Ch. 5 2nd Law of Thermodynamics
- Maxwell Relations
- We also have
- But we also know that, for an exact differential
- Which can be verified by the equation above.
Knowing that we can take the appropriate
differentials of T and p to get the 1st Maxwell
relationship
12Ch. 5 2nd Law of Thermodynamics
- Maxwell Relations
- The other Maxwell relations can be derived in a
similar manner and are given by
13Ch. 5 2nd Law of Thermodynamics
- Some Discussion
- dS ? ?Q/T is a general statement of the 2nd Law.
- Max heat that can be absorbed by a system is TdS.
- Any spontaneous, irreversible process occurring
within an isolated system, not involving external
forces has Sf gt Si. - The state of maximum entropy is a state of
stable equilibrium. - This is where the oft-quoted statement about the
entropy of the universe increasing comes from.
14Ch. 5 2nd Law of Thermodynamics
- Non-Compensated Heat
- Rather than deal with the inequality, we could
write - With this convention, we could write the
fundamental equations without the inequality,
e.g., - In all cases ?Q? is called the non-compensated
heat. - Gives a measure of the irreversibility of the
process, i.e., the smaller ?Q?, the closer the
process is to being reversible.
15Ch. 5 2nd Law of Thermodynamics
- Non-Compensated Heat
- Normally, T and p are defined (for the usual
reversible process) as the equilibrium values in
the system. - When the process is irreversible (inequality
holds) - T represents temperature of sources in contact
with system - p represents external pressure on system
- Condition of irreversibility depend on
differences between these and equilibrium values,
i.e., - (T - Teq) measures thermal irreversibility
- (p - peq) measures mechanical irreversibility
16Ch. 5 2nd Law of Thermodynamics
- Non-Compensated Heat
- Note that when T Teq and p peq, the system is
in equilibrium (and therefore is reversible). - We can therefore write
- Since the internal energy change of the system is
the same, we have - This expresses the total degree of
irreversibility of the process. At equilibrium
?Q? goes to zero.
17Ch. 5 2nd Law of Thermodynamics
- Entropy and Potential Temperature
- The potential temperature is given by
- The enthalpy form of the 1st Law is given by
- If we divide by T we get
- Now if we divide by the mass, md, of the air
parcel, we get
18Ch. 5 2nd Law of Thermodynamics
- Entropy and Potential Temperature
- We now have s, the specific entropy and cpd, the
specific heat of dry air at constant pressure. - Take logarithmic derivatives of the potential
temperature equation to get - The middle term on the right is zero. If we
multiply through by cpd, we get
19Ch. 5 2nd Law of Thermodynamics
- Entropy and Potential Temperature
- The right hand sides of our equations for
potential temperature and specific entropy are
the same, so we have - Leading to the final result
- Changes in entropy (for a reversible process) are
directly proportional to changes in potential
temperature. - Adiabatic (reversible) processes are isentropic.
20Ch. 5 2nd Law of Thermodynamics
- Entropy and Potential Temperature
- We could write a similar equation for the
extensive variable, S, as - What about an irreversible adiabatic process with
ds gt 0? - For any adiabatic process, d? 0 ? ds for an
irreversible process. - Entropy increase is due to irreversible work
(uncompensated heat), such as frictional
dissipation. - Isentropic equals adiabatic, but not always the
other way.