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Momentum & Center of ma
ass
Topics:
•
•
•
•
•
•
Impulse
Momentum
The impulse-momentum
Th
i
l
t
theorem
Center of mass
Conservation of momentum
Inelastic collisions
Sample question:
Male rams butt heads at high spe
eeds in a ritual to assert their
dominance. How can the force off this collision be minimized so as
to avoid damage to their brains?
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-1
Impulse
The force of the foot
on the ball is an
impulsive force.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-8
Graphical Interpretation of Impulse
J = Impulse = area under
the force curve = Favg Δt
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-9
Momentum
Momentum is the product of an
n object’s mass and its velocity:
→
→
p = mv
m
The unit of momentum is kg m/s; there is no
derived unit for momentum.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-10
The Impulse-Momentum Theorem
Impulse causes a change in momentum:
→
→
→
→
J =pf - pi = ∆p
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-11
Example
A 0.5 kg hockey puck slides to the right at 10 m/s. It is hit with
a hockey stick that exerts the force
f
shown. What is its
approximate final speed?
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-12
Two 1-kg stationary cue balls are struck by cue sticks. The cues
exert the forces shown. Which ba
all has the greater final speed?
A. Ball 1
B. Ball 2
C Both balls have the same final speed
C.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-13
Answer
Two 1-kg stationary cue balls are struck by cue sticks. The cues
exert the forces shown. Which ba
all has the greater final speed?
C Both balls have the same final speed
C.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-14
Definition of
impulse:
G
G G
J = Δp = FΔt
One can also define an average impulse when
the force is variable.
v
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Example
A car traveling at 20 m/s crashes into a bridge abutment.
Estimate the force on the driver iff the driver is stopped by
A. a 20-m-long
20
row off water-fille
f ed barrels
B. the crumple zone of her car (~1
( m). Assume a constant
acceleration.
l ti
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-16
Example
A 500 kg rocket sled is coasting
g at 20 m/s. It then turns
on its rocket engines for 5.0 s, with a thrust of 1000 N.
What is its final speed?
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-17
Example: A force of 30 N is applied for 5 sec to
each of two bodies of
o different masses.
30 N
Take m1<m2
m1 or m2
(a) Which mass has tthe greater moment
momentum
m
change?
Si
Since
th same force
the
f
is
i
Δp = FΔt
applied to each mass for the
same inte
erval, Δp is the same
for both masses.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Example continued:
(b) Which mass has th
he greatest velocity
chang
ge?
Since bo
oth masses have the
Δp
Δv =
same Δp,
Δ the smaller mass
Δp
m
(mass 1) will have the larger
cha
hange in
i velocity.
l it
((c)) Which mass ha
as the greatest
g
accelerattion?
Δv
Since
a∝
∝Δv
the
mass
with
the
a=
greater ve
elocity change will have
Δt
the gre
eatest acceleration
acceleration.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
The Law of Conservation of
o Momentum
In terms of the initial and final total
t
momenta:
→
→
Pf = Pi
In terms of components:
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-18
Example
A curling stone, with a mass off 20.0 kg, slides across the ice
at 1.50 m/s. It collides head on
n with a stationary 0.160-kg
hockey puck
puck. After the collision
n the puck’s
n,
puck s speed is 2
2.50
50
m/s. What is the stone’s final velocity?
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-20
Example
p A rifle has a mas
ss of 4.5 kg
g and it fires a
bullet of 10.0 grams at a muzzle
m
speed of 820 m/s.
What is the recoil speed
p
of the rifle as the bullet
leaves the
e barrel?
Ass long
o g as the
e rifle
e is
s horizontal,
ho o a , there
e e will be
no net external force acting
a
on the rifle-bullet
system and momentu
um will be conserved.
pi = p f
0 = mb vb + mr vr
⎛ 0.01 kgg ⎞
mb
⎟⎟820 m/s = −1.82 m/s
∴ vr = −
vb = −⎜⎜
mr
g ⎠
⎝ 44.55 kg
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Center of
o Mass
The center of mass (CM)) is the point representing
the mean (average) po
osition of the matter in a
body This point need n
body.
not be located within the
bo
ody.
Th center
The
t off mass (of
( f a two
t
body
b d system)
t ) iis
found from:
x cm
m1 x1 + m 2 x 2
=
m1 + m 2
This is a “weighted” avera
age of the positions of the
particles that compose a body
body. (A larger mass is
more im
mportant.)
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
In 2-dimensions
write
∑m x
=
∑m
i i
xcm
i
i
i
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
∑m y
=
∑m
i
ycm
i
i
i
i
18
Example:
p Particle A is at the
t origin
g and has a mass
of 30.0 grams. Particle B has a mass of
grams. Where mus
st p
particle B be located so
10.0 g
that the center of mass (marked with a red x) is
p t ((2.0 cm,, 5.0 cm)?
)
located at the point
y
x
A
xcmm
ma xa + mb xb
mb xb
=
=
ma + mb
ma + mb
ycm
c
ma ya + mb yb
mb yb
=
=
ma + mb
ma + mb
x
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Example continued:
xcm =
(10 g )xb
10 g + 30g
xb = 8 cm
= 2 ccm
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
ycm =
(10 g ) yb
30 g + 10 g
yb = 20 cm
= 5 cm
20
Example
p The p
positions of
o three p
particles are ((4.0
m, 0.0 m), (2.0 m, 4.0 m),
m and (-1.0 m, -2.0 m).
The masses are 4.0 kg,
kg, 6.0 kg,
g, and 3.0 kg
g
respectively. What is the
e location of the center of
masss?
y
2
1
x
3
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
21
Example continued:
xcm
m1 x1 + m2 x2 + m3 x3
=
m1 + m2 + m3
(
4 kg )(4 m ) + (6 kg )(2 m ) + (3 kg )(− 1 m )
=
(4 + 6 + 3) kg
k
= 1.92 m
ycm
m1 y1 + m2 y2 + m3 y3
=
m1 + m2 + m3
(
4 kg )(0 m ) + (6 kg )(4 m ) + (3 kg )(− 2 m )
=
(4 + 6 + 3) kg
k
= 1.38 m
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22
Motion of the Center
C
of Mass
F an extended
For
t d db
body,
d it can be
b shown
h
th
thatt
p = mv
vcm.
F
From
this
thi it ffo
ollows
ll
th
thatt
ΣFext = ma
m cm.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Collisions in One
O and Two
Dimension
Di
i
When there are no exte
ernal forces present
present, the
momentum of a system
m will remain unchanged.
(pi = pf)
If the kinetic energy
gy beforre and after an interaction
is the same, the “collisio
on” is said to be perfectly
elastic. If the kinetic energy changes, the collision
is inelastic.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Inelastic Collisions
If, after a collision, the
e bodies remain stuck
together the loss off kinetic energy is a
together,
maximum. This type
e of collision is called
perfectly inelastic.
inelastic
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Slide 9-21
Example
p ((text p
problem 7.41):
) In a railroad freight
g
yard, an empty freight carr of mass m rolls along a
straight
g level track at 1.0 m/s and collides with an
initially stationary, fully loaded, boxcar of mass
p e together
g
upon
p collision.
4.0m. The two cars coupl
(a) What is the speed of the two cars after the
collisio
on?
pi = p f
p1i + p2i = p1 f + p2 f
m1v1 + 0 = m1v + m2 v = (m1 + m2 )v
⎛ m1 ⎞
⎟⎟v1 = 0.2 m/s
∴ v = ⎜⎜
⎝ m1 + m2 ⎠
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26
Example continued:
( ) Suppose
(b)
pp
instead tha
at both cars are at rest
after the collision. With
h what speed was the
loaded boxcar moving be
efore the collision if the
empty one had v1i = 1.0 m/s.
pi = p f
p1i + p2i = p1 f + p2 f
m1v1i + m2 v2i = 0 + 0
⎛ m1 ⎞
∴ v2i = −⎜⎜ ⎟⎟v1i = −0.25 m/s
⎝ m2 ⎠
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27
Example:
p Ap
projectile
j
of 1.0 kg
g mass approaches
pp
a
stationary body of 5.0 kg
g mass at 10.0 m/s and,
after colliding,
g, rebounds
s in the reverse direction
along the same line with a speed of 5.0 m/s. What
is the speed
p
of the 5.0 kg
g mass after the collision?
pi = p f
p1i + p2i = p1 f + p2 f
m1v1i + 0 = m1v1 f + m2 v2 f
v2 f
m1
(v1i − v1 f )
=
m2
1.0 kg
(10 m/ss − (− 5.0 m/s )) = 3.0 m/s
=
5.0 kg
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28
Example
Jack stands at rest on a skateb
board. The mass of Jack and
the skateboard together is 75 kg.
k Ryan throws a 3.0 kg ball
horizontally to the right at 4
4.0
0m
m/s to Jack,
Jack who catches itit.
What is the final speed of Jack
k and the skateboard?
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Slide 9-22
Example
A 10 g bullet is fired into a 1.0 kg
k wood block, where it
lodges. Subsequently, the bloc
ck slides 4.0 m across a floor
(µk = 0
0.20
20 for wood on wood)
wood). W
What was the bullet’s
bullet s speed?
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Slide 9-23
Perfectly elas
stic collision
Ap
perfectly
y elastic co
ollision is defined as
one in which there is no loss of kinetic
gy in th
he collision.
energy
http://ww
ww.walterfendt.de/ph14
p 4e/collision.htm
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
One - Dimensionall Elastic Collisions
Consider two collidding objects with masses m1 and m2 ,
G
G
G
G
initial velocities v1i and v2i , and final velocities v1 f and v2 f ,
respectively.
Both linear momentum and kinetic enerrgy are conserved.
Li
Linear
momentum conservation:
i
m1v1i + m1v2i = m1v1 f + m1v2 f
2
2
m1v12i m1v22i m1v1 f m2 v2 f
Kinetic energy conservation:
+
+
=
2
2
2
2
wns, v1 f and v1 f .
We have two equations and two unknow
( 1)
(eq.
(eq. 2)
If we solve
l equations
ti
1 andd 2 for
f v1 f an
ndd v1 f we gett the
th following
f ll i solutions:
l ti
v1 f =
v2 f
m1 − m2
2m2
v1i +
v2i
m1 + m2
m1 + m2
2m1
m2 − m1
=
v1i +
v2i
m1 + m2
m1 + m2
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
(9-
o Dimensions :
Collisions in Two
In this section we will remove the restriction that the
colliding objects move
m
along one axis. Instead we assume
that the two bodiees that participate in the collision
move in the xy -plaane. Their masses are m1 and m2 .
G
G
G
G
The linear momentum of the system is co
onserved: p1i + p2i = p1 f + p2 f .
If the system is elastic the kinetic energy is also conserved: K1i + K 2i = K1 f + K 2 f .
We assume that m2 is stationary and that after the collision particle 1 and
particle 2 move at angles θ1 and θ 2 with the
t initial direction of motion of m1.
In this case the conservation of momentu
um and kinetic energy take the form:
x − axis: m1v1i = m1v1 f cos θ1 + m2 v2 f cos θ 2 (eq. 1)
y − axis: 0 = −m1v1 f sin θ1 + m2 v2 f sin θ 2 (eq. 2)
1
1
1
m1v12i = m1v22 f + m2 v22 f (eq. 3) We have three equations and seven variables:
2
2
2
Two masses: m1 , m2 ; three speeds: v1i , v1 f , v2 f ; and two angles: θ1 , θ 2 . If we know
the values of four of these parameters wee can calculate the remaining three.
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Example:
p Body
y A of mass M has an original
g
velocity
y
of 6.0 m/s in the +x-direc
ction toward a stationary
bodyy (B)
( ) of the same mass.
m
After the collision,,
body A has vx=+1.0 m/s and
a vy=+2.0 m/s. What is
the
e magnitude
ag ude o
of bodyy B’ss velocity
e oc y a
after
e the
e
collis
sion?
Fi l
Final
Initial
A
A
vAi
B
B
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
Example continued:
x
momentum
pix = p fx
p + p := p + p
1ix
2 ix
1 fx
y
momentum
piy = p fy
:
2 fx
m1v1ix + 0 = m1v1 fx + m2 v2 fx
Solve for v2fx:
v2 fx =
m1v1ix − m1v1 fx
m2
= v1ix − v1 fx
= 5.00 m/s
The mag. of v2 is
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley.
p1iy + p2iy = p1 fy + p2 fy
0 + 0 = m1v1 fy + m2 v2 fy
Solve for
v2fy:
v2 fy =
− m1v1 fy
m2
= −v1 fy
= −2.00 m/s
/
v2 f = v
2
2 fy
+v
2
2 fx
= 5.40 m/s
Fig. 07.20
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