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Transcript
Mastering Physics 19.32
• Requires Section 19.8
• Will re-score to make 19.32 extra credit
Before We Start
• Why is T  Ktrans?
• Why is C larger when there are more
modes?
• Why does energy partition between
modes?
Thermodynamic Paths
energy transfers
§ 19.3–19.4
Energy Transfers
Between system and surroundings
• Work
• Heat
Work
From a volume change of the system
W = V p dV
V2
1
Heat
From a temperature difference
dQ/dT  Tsurr – Tsys
Work and Heat
Depend on the path taken between initial
and final states.
CPS Question
The work done by a
thermodynamic
system in a cyclic
process (final state is
also the initial state) is
zero.
A. True.
B. False.
Source: Y&F, Figure 19.12
Cyclic Process
W0
Is the system a limitless source of work?
(Of course not.)
W
Source: Y&F, Figure 19.12
Work between States
p
V
W is not uniquely determined by initial and
final states
What Are the Processes?
p
V
The more work a path between two states
produces, the more heat must be provided.
Group Work
1. Qualitatively sketch a pV plot for each
described process AB.
a)
b)
c)
d)
Volume is gradually doubled with no heat input, then
heated at constant volume to the initial temperature.
System is heated at constant pressure until volume
doubles, then cooled at constant volume to the initial
temperature.
System is allowed to expand into a vacuum (free
expansion) to twice its volume.
Volume is gradually doubled while maintaining a
constant temperature.
Group Work
2. Rank the processes in descending order
of W.
3. Rank the processes in descending order
of Q.
Conservation of Energy
DE of a system =
work done on the system
+
heat added to the system
Internal Energy U
US
K
+
SS
V
i
i
i j<i ij
• Ki = kinetic energy of molecule i wrt com
• Vij = intermolecular potential energy of i
and j
Does not include potential or kinetic energy
of bulk object
Each thermodynamic state has a unique U
(U is a state function)
CPS Question
All other things being equal, adding heat to a
system increases its internal energy U.
A. True.
B. False.
CPS Question
All other things being equal, lifting a system
to a greater height increases its internal
energy U.
A. True.
B. False.
CPS Question
All other things being equal, accelerating a
system to a greater speed increases its
internal energy U.
A. True.
B. False.
CPS Question
All other things being equal, doing work to
compress a system increases its internal
energy U.
A. True.
B. False.
First law of Thermodynamics
DU = Q – W
DU is path-independent
Cyclic Processes
DU = U1 – U1 = 0
so
Q–W=0
so
Q=W
• Work output = heat input
Work out = Heat in
Does this mean cyclic processes convert
heat to work with 100% efficiency?
(Of course not.)
Waste heat is not recovered.
Example Problem 19.17
A thermodynamic cycle consists of two
closed loops, I and II.
d) In each of the loops, I
and II, does heat flow into or
out of the system?
c) Over one complete cycle,
does heat flow into or out of
the system?
I
p
II
V