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Transcript 
Chapter 6
Work and Energy
continued
Seat reassignments
• 
• 
• 
• 
• 
Fisher, N
Hutchison
Sanders
Bell
Maxwell
B18
B19
B20
C1
C2
6.3 Gravitational Potential Energy
GRAVITATIONAL POTENTIAL ENERGY
Energy of mass m due to its position relative to the surface of the earth.
Position measured by the height h of mass relative to an arbitrary zero level:
PE replaces Work by gravity
in the Work-Energy Theorem
Work-Energy Theorem becomes Mechanical Energy Conservation:
KE f + PE f = KE0 + PE0
E f = E0
Initial total energy, E0 = KE0 + PE0 doesn't change.
It is the same as final total energy, E f = KE f + PE f .
Another way (equivalent) to look at Mechanical Energy Conservation:
( KE
f
− KE0 ) + ( PE f − PE0 ) = 0
ΔKE
+
ΔPE
=0
Any increase (decrease) in KE is balanced
by a decrease (increase) in PE.
These are used if only Conservative Forces act on the mass.
(Gravity, Ideal Springs, Electric forces)
6.5 The Conservation of Mechanical Energy
Sliding without friction: only gravity does work.
Normal force of ice is always
perpendicular to displacements.
6.4 Conservative Versus Nonconservative Forces
In many situations both conservative and non-conservative
forces act simultaneously on an object, so the work done by
the net external force can be written as
WC = work by conservative force
WNet = WC + WNC
such as work by gravity WG
But replacing WC with − (PE f − PE0 )
Work-Energy Theorem becomes:
KE f + PE f = KE0 + PE0 + WNC
Ef
= E0
+ WNC
work by non-conservative forces will
add or remove energy from the mass
E f = KE f + PE f ≠ E0 = KE0 + PE0
Another (equivalent) way to think about it:
( KE
f
− KE0 ) + ( PE f − PE0 ) = WNC
ΔKE
+ ΔPE
= WNC
if non-conservative forces
do work on the mass, energy
changes will not sum to zero
6.5 The Conservation of Mechanical Energy
But all you need is this:
KE f + PE f = KE0 + PE0 + WNC
non-conservative forces
add or remove energy
If WNC ≠ 0, then E f ≠ E0
If the net work on a mass by non-conservative forces is zero,
then its total energy does not change:
If WNC = 0, then E f = E0
KE f + PE f = KE0 + PE0
6.5 The Conservation of Mechanical Energy
Example 8 A Daredevil Motorcyclist
A motorcyclist is trying to leap across the canyon by driving
horizontally off a cliff 38.0 m/s. Ignoring air resistance, find
the speed with which the cycle strikes the ground on the other
side.
6.5 The Conservation of Mechanical Energy
mghf + 12 mvf2 = mgh0 + 12 mv02
ghf + v = gh0 + v
1
2
2
f
1
2
2
0
6.5 The Conservation of Mechanical Energy
ghf + v = gh0 + v
1
2
2
f
2
0
1
2
vf = 2g ( h0 − hf ) + v
2
0
(
vf = 2 9.8m s
2
)(35.0m ) + (38.0m s)
2
= 46.2m s
6.5 The Conservation of Mechanical Energy
Conceptual Example 9 The Favorite Swimming Hole
The person starts from rest, with the rope
held in the horizontal position,
swings downward, and then lets
go of the rope, with no air
resistance. Two forces
act on him: gravity and the
tension in the rope.
Note: tension in rope is always
perpendicular to displacement,
and so, does no work on the mass.
The principle of conservation of energy
can be used to calculate his final speed.
6.6 Nonconservative Forces and the Work-Energy Theorem
Example 11 Fireworks
Assuming that the nonconservative force
generated by the burning propellant does
425 J of work, what is the final speed
of the rocket. Ignore air resistance.
E f = E0 + WNC
(
) (
WNC = mghf + 12 mvf2 − mgh0 + 12 mv02
= mg ( hf − h0 ) + 12 mvf2 + 0
vf2 = 2WNC m − 2g ( hf − h0 )
(
)
)
= 2 ( 425 J ) / ( 0.20 kg ) − 2 9.80m s 2 ( 29.0 m )
vf = 61 m/s
6.7 Power
DEFINITION OF AVERAGE POWER
Average power is the rate at which work is done, and it
is obtained by dividing the work by the time required to
perform the work.
Work W
P=
=
Time
t
Note: 1 horsepower = 745.7 watts
⎛ s⎞
W Fs
P= =
= F ⎜ ⎟ = Fv
t
t
⎝ t⎠
6.7 Power
6.8 Other Forms of Energy and the Conservation of Energy
THE PRINCIPLE OF CONSERVATION OF ENERGY
Energy can neither be created not destroyed, but can
only be converted from one form to another.
Heat energy is the kinetic or vibrational energy of molecules.
The result of a non-conservative force is often to remove
mechanical energy and transform it into heat.
Examples of heat generation: sliding friction, muscle forces.
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