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Transcript 
Fig. 5-2, p. 211
Energy
Energy
Kinetic:
Energy
Kinetic:
Mechanical – moving car
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Sound – moving waves of gas
compression and expansion
Energy
Kinetic:
Potential:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Sound – moving waves of gas
compression and expansion
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Sound – moving waves of gas
compression and expansion
Potential:
Gravitational – the eraser
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Sound – moving waves of gas
compression and expansion
Potential:
Gravitational – the eraser
Chemical – gasoline
Energy
Kinetic:
Mechanical – moving car
Thermal – moving molecules
Electrical – moving charge
Sound – moving waves of gas
compression and expansion
Potential:
Gravitational – the eraser
Chemical – gasoline
Electrostatic – +..- attraction (static E)
Temperature reflects molecular kinetic energy
(thermal)
Fig. 5-3, p. 211
Law of Conservation of Energy
Law of Conservation of Energy
The total energy of the universe is constant
Law of Conservation of Energy
The total energy of the universe is constant
System: define carefully
Law of Conservation of Energy
The total energy of the universe is constant
System: define carefully
System + Surroundings = Universe
All nomenclature is from the
point of view of the system
Exothermic: energy transfer from system
(out of)
Fig. 5-6, p. 214
Exothermic: energy transfer from system
(out of)
All nomenclature is from the point of view of the system
Fig. 5-6, p. 214
Endothermic: energy transfer into system
All nomenclature is from the point of view of the system
Fig. 5-6, p. 214
Temperature reflects molecular kinetic energy
(thermal)
T = 21°C
T = 55°C
Fig. 5-3, p. 211
Temperature reflects molecular kinetic energy
(thermal)
T = 21°C
T = 55°C
Transfer of thermal
energy is spontaneous
Fig. 5-3, p. 211
Temperature reflects molecular kinetic energy
(thermal)
T = 21°C
T = 55°C
T = 38°C
T = 38°C
Thermal Equilibrium
Transfer of thermal
energy is spontaneous
Continues until the system
reaches thermal equilibrium
Fig. 5-3, p. 211
Temperature reflects molecular kinetic energy
T = 21°C
T = 55°C
T = 38°C
T = 38°C
Thermal Equilibrium
Temperature reflects molecular kinetic energy
T = 21°C
T = 55°C
T = 38°C
T = 38°C
Thermal Equilibrium
T = 21°C
T = 55°C
T = x °C
T = x°C
Temperature reflects molecular kinetic energy
T = 21°C
T = 55°C
T = 38°C
T = 38°C
Thermal Equilibrium
T = 21°C
T = 55°C
T = x °C
T = x°C
Is x (1) less than 38°C or (2) greater than 38°C?
Temperature reflects molecular kinetic energy
Mass matters
T = 21°C
T = 55°C
T = x °C
T = x°C
Is x (1) less than 38°C or (2) greater than 38°C?
Temperature reflects molecular kinetic energy
Mass matters
Heat Capacity matters
T = 21°C
T = 55°C
T = x °C
T = x°C
Is x (1) less than 38°C or (2) greater than 38°C?
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
C
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
C
m
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
C
m
∆T
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
C
m
∆T
p. 216
q = CmΔT
Energy (q) required to change the
temperature (∆T) of a given mass (m) of a
substance with a specific heat capacity (C)
€
C
m
∆T
p. 216
q = CmΔT
€
C
m
∆T
p. 216
q = CmΔT
Specific heat capacity
(per gram)
€
C
m
∆T
p. 216
q = CmΔT
Specific heat capacity
(per gram)
mass
€
C
m
∆T
p. 216
q = CmΔT
Specific heat capacity
(per gram)
Temperature
(in Kelvin)
mass
€
C
m
∆T
p. 216
The absolute temperature scale
(Kelvin)
TK = TC + 273
5
TC = (TF − 32)
9
What’s special about Kelvin?
1) He copyrighted the name
€
2) The scale reflects
molecular motion
(0=no motion)
3) Larger numbers reflect better precision
The absolute temperature scale
(Kelvin)
TK = TC + 273
5
TC = (TF − 32)
9
What’s special about Kelvin?
1) He copyrighted the name
€
2) The scale reflects
molecular motion
(0=no motion)
3) Larger numbers reflect better precision
Always (always, always) use Kelvin
Always (always, always) use Kelvin
OK, there’s one place you can cheat: ∆T
Always (always, always) use Kelvin
OK, there’s one place you can cheat: ∆T
Why can you cheat?
Always (always, always) use Kelvin
OK, there’s one place you can cheat: ∆T
Why can you cheat?
final
ΔT = TK
ΔT = (TC
initial
− TK
final
+ 273) − (TC
initial
+ 273)
ΔT = TCfinal + 273 − TCinitial − 273
final
ΔT = TC
initial
− TC
Fig. 5-8, p. 217
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