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Thermodynamics

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Title: Thermodynamics


1
Thermodynamics
2
First Law of ThermodynamicsEnergy Conservation
The change in internal energy of a system (DU) is
equal to the heat flow into the system (Q) minus
the work done by the system (W)
DU Q - W
Increase in internalenergy of system
Heat flow into system
Equivalent ways of writing 1st Law Q DU W
07
3
Work Done by a System
The work done by the gas as it contracts is A)
Positive B) Zero C) Negative
W F d cosq P A d P A Dy P DV
W p ?V For constant Pressure W gt 0 if ?V gt
0 expanding system does positive work W lt 0 if
?V lt 0 contracting system does negative work W
0 if ?V 0 system with constant volume does
no work
13
4
Thermodynamic Systems and P-V Diagrams
  • ideal gas law PV nRT
  • for n fixed, P and V determine state of system
  • T PV/nR
  • U (3/2)nRT (3/2)PV
  • Examples
  • which point has highest T?
  • which point has lowest U?
  • to change the system from C to B,
  • energy must be added to system

P
A
B
P1 P3
C
V
V1 V2
17
5
Special PV Cases
  • Constant Pressure (isobaric)
  • Constant Volume
  • (isochoric)
  • Constant Temp DU 0
  • Adiabatic Q0

42
6
First Law of ThermodynamicsIsobaric Example
2 moles of monatomic ideal gas is taken from
state 1 to state 2 at constant pressure p1000
Pa, where V1 2m3 and V2 3m3. Find T1, T2, DU,
W, Q. (R8.31 J/k mole)
21
7
First Law of ThermodynamicsIsochoric Example
2 moles of monatomic ideal gas is taken from
state 1 to state 2 at constant volume V2m3,
where T1120K and T2 180K. Find Q.
P
P2 P1
2
1
V
V
24
8
Example complete cycle
Wtot ??
27
9
WORK Question
  • If we go the opposite direction for the cycle
    (4,3,2,1) the net work done by the system will
    be
  • A) Positive B) Negative

30
10
PV Question
  • Shown in the picture below are the pressure
    versus volume graphs for two thermal processes,
    in each case moving a system from state A to
    state B along the straight line shown. In which
    case is the work done by the system the biggest?
  • A. Case 1
  • B. Case 2
  • C. Same

P(atm)
P(atm)
A
B
4
4
A
B
2
2
Case 1
Case 2
3
9
3
9
V(m3)
V(m3)
Net Work area under P-V curve Area the same in
both cases!
29
11
PV Question2
  • Shown in the picture below are the pressure
    versus volume graphs for two thermal processes,
    in each case moving a system from state A to
    state B along the straight line shown. In which
    case is the change in internal energy of the
    system the biggest?
  • A. Case 1
  • B. Case 2
  • C. Same

?U 3/2 ?(pV) Case 1 ?(pV) 4x9-2x330
atm-m3 Case 2 ?(pV) 2x9-4x3 6 atm-m3
31
12
PV Question3
  • Shown in the picture below are the pressure
    versus volume graphs for two thermal processes,
    in each case moving a system from state A to
    state B along the straight line shown. In which
    case is the heat added to the system the biggest?
  • A. Case 1
  • B. Case 2
  • C. Same

Q ?U W W is same for both ?U is larger for
Case 1 Therefore, Q is larger for Case 1
34
13
First Law Questions
Q DU W
Some questions
  • Which part of cycle has largest change in
    internal energy, DU ?
  • 2 ? 3 (since U 3/2 pV)
  • Which part of cycle involves the least work W ?
  • 3 ? 1 (since W pDV)
  • What is change in internal energy for full
    cycle?
  • ?U 0 for closed cycle (since both p V are
    back where they started)
  • What is net heat into system for full cycle
    (positive or negative)?
  • ?U 0 ? Q W area of triangle (gt0)

37
14
Question
Consider a hypothetical device that takes 1000 J
of heat from a hot reservoir at 300K, ejects 200
J of heat to a cold reservoir at 100K, and
produces 800 J of work. Does this device violate
the first law of thermodynamics ? 1. Yes 2. No
  • W (800) Qhot (1000) - Qcold (200)
  • Efficiency W/Qhot 800/1000 80

45
15
Reversible?
  • Most physics processes are reversible, you
    could play movie backwards and still looks fine.
    (drop ball vs throw ball up)
  • Exceptions
  • Non-conservative forces (friction)
  • Heat Flow
  • Heat never flows spontaneously from cold to hot

47
16
Summary
  • 1st Law of Thermodynamics Energy Conservation

Q DU W
P
  • point on p-V plot completely specifies state
    of system (pV nRT)
  • work done is area under curve
  • U depends only on T (U 3nRT/2 3pV/2)
  • for a complete cycle DU0 ? QW

V
50
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