To solve this problem it is necessary to apply the concepts related to entropy. Entropy can be defined as the change between heat energy and body temperature. For this case we will analyze the entropy in the cold body and later in the hot body. From there we will find the entropy difference
Entropy can be defined as,
[tex]S = \frac{Q}{T}[/tex]
Here,
Q = Heat Flow
T = Temperature
The entropy of the hot reservoir goes down by
[tex]S_1 = \frac{6400J}{610K}[/tex]
The entropy of the "cool" reservoir increases by
[tex]S_2 = \frac{4200J}{320K}[/tex]
[tex]\Delta S = S_2 -S_1[/tex]
[tex]\Delta S = \frac{4200J}{320K}-\frac{6400J}{610K}[/tex]
[tex]\Delta S = 13.125-10.492[/tex]
[tex]\Delta S = 2.633J/K[/tex]
As expected, entropy increased in this process; the entropy lost by the hot side was less than the entropy gained by the cool side.
Answer:
the net change in entropy as a result of this cycle is 2.63 J/K
Explanation:
given information:
high temperature, [tex]T_{H}[/tex] = 610 K
low temperature, [tex]T_{C}[/tex] = 320 K
heat absorbed, [tex]Q_{H}[/tex] = 6400 J
work, W = 2200 J
to calculate the net change in entropy as a result of this cycle, we can use the following formula:
ΔS = [tex]\frac{Q_{H} }{T_{H} } +\frac{Q_{C} }{T_{C} }[/tex] and W = [tex]Q_{H}[/tex] - [tex]Q_{C}[/tex]
where
ΔS = the change of entropy
[tex]T_{H}[/tex] = the high temperature
[tex]T_{C}[/tex] = low temperature
[tex]Q_{H}[/tex] = absorbed heat
[tex]Q_{C}[/tex] = released heat
first, we determine the [tex]Q_{C}[/tex]
W = [tex]Q_{H}[/tex] - [tex]Q_{C}[/tex]
[tex]Q_{C}[/tex] = 6400 - 2200
= 4200 J
therefore,
ΔS = [tex]\frac{Q_{H} }{T_{H} } +\frac{Q_{C} }{T_{C} }[/tex]
= [tex]-\frac{6400}{610} + \frac{4200}{320}[/tex]
= - 10.49 + 13.125
= 2.63 J/K
