The second integral in the previous relation is recognized as the entropy
change S 1 S 2. Therefore,
which can be rearranged as
(7–7)
It can also be expressed in differential form as
(7–8)
where the equality holds for an internally reversible process and the
inequality for an irreversible process. We may conclude from these equa-
tions that the entropy change of a closed system during an irreversible
process is greater than the integral of dQ/Tevaluated for that process. In the
limiting case of a reversible process, these two quantities become equal. We
again emphasize that Tin these relations is the thermodynamic temperature
at the boundarywhere the differential heat dQis transferred between the
system and the surroundings.
The quantity SS 2 S 1 represents the entropy changeof the system.
For a reversible process, it becomes equal to
2
1 dQ/T, which represents the
entropy transferwith heat.
The inequality sign in the preceding relations is a constant reminder that
the entropy change of a closed system during an irreversible process is
always greater than the entropy transfer. That is, some entropy is generated
or createdduring an irreversible process, and this generation is due entirely
to the presence of irreversibilities. The entropy generated during a process is
called entropy generationand is denoted by Sgen. Noting that the difference
between the entropy change of a closed system and the entropy transfer is
equal to entropy generation, Eq. 7–7 can be rewritten as an equality as
(7–9)
Note that the entropy generation Sgenis always a positivequantity or zero.
Its value depends on the process, and thus it is nota property of the system.
Also, in the absence of any entropy transfer, the entropy change of a system
is equal to the entropy generation.
Equation 7–7 has far-reaching implications in thermodynamics. For an
isolated system (or simply an adiabatic closed system), the heat transfer is
zero, and Eq. 7–7 reduces to
(7–10)
This equation can be expressed as the entropy of an isolated system during
a process always increases or, in the limiting case of a reversible process,
remains constant. In other words, it neverdecreases. This is known as the
increase of entropy principle.Note that in the absence of any heat transfer,
entropy change is due to irreversibilities only, and their effect is always to
increase entropy.
¢Sisolated 0
¢SsysS 2 S 1
2
1
¬
dQ
T
Sgen
dS
dQ
T
S 2 S 1
2
1
¬
dQ
T
2
1
¬
dQ
T
S 1 S 2 0
336 | Thermodynamics
Process 1-2
(reversible or
irreversible)
1
2
Process 2-1
(internally
reversible)
FIGURE 7–5
A cycle composed of a reversible and
an irreversible process.