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Transcript
Phys101 Lectures 14, 15, 16
Momentum and Collisions
Key points:
• Momentum and impulse
• Condition for conservation of momentum and why
• How to solve collision problems
• Centre of mass
Ref: 9-1,2,3,4,5,6,7,8,9.
Page 1
Momentum is a vector:
It’s a quantity that represents the amount and direction of motion.
It was once called “the quantity of motion”. Now we know that
kinetic energy is another quantity of motion.



nd

d
v
d
p
Newton’s 2 Law
F  ma  m

dt
dt
tf




F
dt

p

p


p
f
i

ti
where

 tf 

J   Fdt  Favet is called the impulse of force F .
ti
(area under the F-t curve)
Impulse-momentum principle : The net impulse on an object is
equal to the change in momentum of the object.


J  p
Example 9-1: Force of a tennis serve.
For a top player, a tennis ball may leave the
racket on the serve with a speed of 55 m/s
(about 120 mi/h). If the ball has a mass of
0.060 kg and is in contact with the racket for
about 4 ms (4 x 10-3 s), estimate the average
force on the ball.
[Solution]



J  Favet  p
p mv  0
Fave 

t
t
0.06  55

0.004
 800 ( N )
x
i-clicker question 14-1
A 0.140-kg baseball is dropped from rest. It has a speed of
1.20 m/s just before it hits the ground. It rebounds with a
speed of 1.00 m/s. The ball is in contact with the ground
for 0.0140 s. What is the average force exerted by the
ground on the ball during that time?
A) 2.00 N
x


B) 10.00 N
F t  p
C) 22.0 N
Fx t  p x
D) 24.0 N
p x m( v fx  vix )
Fx 

E) 12.0 N
t
t
0.1401.00  ( 1.20 )

0.014
 22 ( N )
MasteringPhysics Assignment #6
Impulse-Momentum Theorem, Part I
• Consider a particle of mass m=5.00kg moving along the x axis. It is
at rest at t=0.00 sec. A varying force F(t)=6.00t2-4.00t+3.00 is
acting on the particle between t=0.00 sec and t=5.00sec. Find the
speed v of the particle at t=5.00 sec.

 




J  p  p f  pi  m( v f  vi )  mv f
x
 t2 
J   Fdt
t1
t2
5



J x   Fx dt   6t 2  4t  3 dt  2t 3  2t 2  3t
t1

0
 

5
0

 2( 5 )3  2( 5 )2  3( 5 )  2( 0 )3  2( 0 )2  3( 0 )
 215 ( N  S )
v fx 
Jx
215

 43 ( m / s )
m
5
Many-body System
Two students pulling each other on ice.
Internal forces:
External forces:


F12 and F21 .


 
m1 g , m2 g , FN1 and FN1
1

F12
2

F21




 
 
dp1
dp2
, m2 g  FN 2  F21 
Newton’s law: m1 g  FN 1  F12 
dt
dt
Adding the two equations




 
 
dp1 dp2
m1 g  FN 1  m2 g  FN 2  F12  F21 

dt
dt




dP
 Fext   Fint  dt . P is the total momentum of the system

Since the internal forces always cancel,

 Fext

dP

dt



F21   F12 ,

 Fint  0
(only external forces can change the total momentum)
Demo
Conservation of Momentum

When  Fext  0,


dP
 0, i.e., P  cons tan t
dt
This is the law of conservation of linear
momentum:
When the net external force on a system of objects is zero,
the total momentum of the system remains constant.
Note 1: If one of the components of the net external
force is zero, the corresponding component of the total
momentum of the system is conserved (even though the
total momentum vector may or may not be conserved).
Note 2: For a one-object system, the condition for
momentum conservation is that the net force acting on
the object is zero.
i-clicker question 14-2
The condition for mechanical energy to be conserved is
(A) It’s a closed system.
(B) The net external force is zero.
(C) No nonconservative work.
(D) The momentum is never conserved.
(E) The momentum is always conserved.
Example 9-4: Rifle recoil.
Calculate the recoil
velocity of a 5.0-kg rifle
that shoots a 0.020-kg
bullet at a speed of 620
m/s.
[Solution]
X-component of external
Force is zero;
Thus the x-component of the total momentum is conserved:
Pxf  Pxi  0
mB vBx  mR vRx  0
mB vBx
0.02  620
vRx  

 2.5 ( m / s )
mR
5
vR  2.5 ( m / s )
Collisions
Momentum is conserved in all
collisions.
Why?
Because the impulse of external
forces can be ignored (much
smaller than internal impulse).
Collisions in which kinetic energy
is conserved as well are called
elastic collisions, and those in
which it is not are called inelastic.
Elastic Collisions in One Dimension
Here we have two objects
colliding elastically. We
know the masses and the
initial speeds.
Since both momentum
and kinetic energy are
conserved, we can write
two equations. This
allows us to solve for the
two unknown final
speeds.
x
Example 9-7: Billiard ball A of mass m moving with speed vA collides
head-on with ball B of equal mass. What are the speeds of the two
balls after the collision, assuming it is elastic? Assume ball B is
initially at rest (vB = 0).
Conservation of momentum:
mvA  mvA  mvB (x - comp)
(1)2  (2) :
0  2vAvB
Solution 1 :
vA  0
vB  v A
Solution 2 :
vB  0
vA  v A
Conservation of kinetic energy:
1 2 1
1
2

mvA  mv A  mvB2
2
2
2
v A  vA  vB
(1)
v A2  vA2  vB2
(2)
Solution 2 should be rejected
because it means no collision.
Inelastic Collisions
With inelastic collisions, some of the initial
kinetic energy is lost to thermal or potential
energy. Kinetic energy may also be gained
during explosions, as there is the addition of
chemical or nuclear energy.
A completely inelastic collision is one in
which the objects stick together afterward,
so there is only one final velocity. v  v
A
B
Example 9-3: Railroad cars collide
A 10,000-kg railroad car, A, traveling at a speed of 24.0 m/s strikes an
identical car, B, at rest. If the cars lock together as a result of the
collision, what is their common speed immediately after the
collision?
Conservation of momentum (x-comp.):
Hit and stick (perfectly inelastic):
Solve:
mvA  mvA  mvB
vA  vB
vA  vB 
vA
2
Example 9-11: Ballistic pendulum.
The ballistic pendulum is a device used to
measure the speed of a projectile, such as a
bullet. The projectile, of mass m, is fired into
a large block of mass M, which is
suspended like a pendulum. As a result of
the collision, the pendulum and projectile
together swing up to a maximum height h.
Determine the relationship between the
initial horizontal speed of the projectile, v,
and the maximum height h.
[Solution] Two events:
1. Hit and stick;
2. Swing .
mv  ( m  M )v
1
( m  M )v2  ( m  M )gh
2
1 m2
Eliminate v :
v 2  ( m  M )gh ,
2 mM
mM
v
m
2 gh
Collisions in Two or Three Dimensions
Example 9-13: Proton-proton collision.
A proton traveling with speed 8.2 x 105 m/s collides elastically with
a stationary proton in a hydrogen target. One of the protons is
observed to be scattered at a 60°angle. At what angle will the
second proton be observed, and what will be the velocities of the
two protons after the collision?
Elastic collision:
mA  mB  m
1 2 1
1
mvA  mvA2  mvB2
2
2
2
i .e., v A2  vA2  vB2 (1)
Conservation of momentum:




 
mv A  mv A  mvB , i .e., v A  v A  vB ,
x : v A  vA cos  A  vB cos  B (2)
y : 0  vA sin  A  vB sin  B
(3)
3 unknowns : vA , vB ,  B .
3 equations : (1), (2), (3).
i-clicker question 14-3
A car with a mass of 1200 kg and a speed of 12 m/s heading north
approaches am intersection. At the same time, a minivan with a
mass of 1300 kg and speed of 24 m/s heading east is also
approaching the intersection. The car and the minivan collide and
stick together. Consider the total momentum and the total kinetic
energy of the two vehicles before and after the collision.
WhatA.is the
velocity
of momentum
the wreckedand
vehicles
just after
the collision?
Both
the total
total kinetic
energy
are



conserved.


Hit and stick:
vC  vV  vR
(N)
B. The total momentum is conservedbut the total ykinetic


Conservation
of momentum:
energy
is not conserved.
pC  pV  PR
C. Neither the total momentum nor the total kinetic energy is
2
2
PR  conserved.
mV vV   mC vC   34400 ( kg  m / s )
x (E)
D. The total kinetic energy is conserved but the total
PR
34400
momentum
is
not conserved.

vR E. The change
 in total momentum
 13.7 ( m equals
/ s ) the change in
pV total
mV  mC 1300  1200
kinetic energy.
  tan
1
pV
1 mV vV
 tan
 65
pC
mC vC

pC 

PR
Center of Mass (CM)
In (a), the diver’s motion is pure translation; in (b)
it is translation plus rotation.
There is one point that moves in the same path a
particle would
take if subjected
to the same force
as the diver. This
point is called the
center of mass
(CM).
Center of Mass (CM)
The general motion of an object can be
considered as the sum of the translational
motion of the CM, plus rotational, vibrational,
or other forms of motion about the CM.
Center of Mass (CM)
For two particles, the center of mass lies closer to the
one with the most mass:
where M is the total mass.
In general,
xCM
mA x A  mB xB
mA y A  mB yB

, yCM 
,
mA  mB
mA  mB
Exercise 9-15: Three particles in
2-D.
Three particles, each of mass
2.50 kg, are located at the
corners of a right triangle
whose sides are 2.00 m and 1.50
m long, as shown. Locate the
center of mass.
[Solution]
xCM 
m A x A  mB xB  mC xC
m A  mB  mC
1
  x A  xB  xC  ( m A  mB  mC )
3
1
 0  2.0  2.0
3
 1.33 ( m )
yCM 
m A y A  mB y B  mC yC
m A  mB  mC
1
  y A  y B  yC 
3
1
 0  0  1.5
3
 0.50 ( m )
Example 9-17: CM of L-shaped flat object.
Determine the CM of the uniform thin L-shaped object shown.
[Solution] The object consists of two
rectangular parts: A and B, whose
centres of mass are (xA, yA) and (xB, yB).
x A  1.03m, y A  0.10m
xB  1.96m, yB  0.74m
mA  t( 2.06  0.20 )
 0.412 t
(   density , t  thickness )
mB  t( 1.48  0.20 )  0.296t
xCM
mA x A  mB xB 0.412 1.03  0.296 1.96


 1.42 ( m )
m A  mB
0.412  0.296
yCM 
mA y A  mB y B 0.412  0.10  0.296  ( 0.74 )

 0.25 ( m )
m A  mB
0.412  0.296
Center of Mass and Translational Motion
The total momentum of a system of particles is equal to the product
of the total mass and the velocity of the center of mass.


PTotal  MvC
The sum of all the forces acting on a system is equal to the total
mass of the system multiplied by the acceleration of the center of
mass:
Therefore, the center of mass of a system of particles
(or objects) with total mass M moves like a single
particle of mass M acted upon by the same net
external force.
Conceptual Example 9-18: A two-stage rocket.
A rocket is shot into the air as shown. At the moment it
reaches its highest point, a horizontal distance d from its
starting point, a prearranged explosion separates it into
two parts of equal mass. Part I is stopped in midair by the
explosion and falls vertically to Earth. Where does part II
land? Assume g = constant.