Transcript Chapter 9
Chapter 9
Linear Momentum and Collisions
Linear momentum
• Linear momentum (or, simply momentum)
point-like object (particle) is
p
of a
p mv
• SI unit of linear momentum is kg*m/s
• Momentum is a vector, its direction coincides with
the direction of velocity
Newton’s Second Law revisited
• Originally, Newton formulated his Second Law in a
more general form
Fnet
dp
dt
• The rate of change of the momentum of an object is
equal to the net force acting on the object
• For a constant mass
Fnet
dp d (mv )
dv
m
ma
dt
dt
dt
Center of mass
• In a certain reference frame we consider a system of
particles, each of which can be described by a mass
and a position vector
• For this system we can define a center of mass:
rCM
mi ri
i
m
i
i
mi ri
i
M
Center of mass of two particles
• A system consists of two particles on the x axis
• Then the center of mass is
rCM
mi ri
i
m
i
mi ri
i
M
i
xCM
m1 x1 m2 x2
m1 m2
yCM
m1 0 m2 0
m1 m2
0
Newton’s Second Law for a system of
particles
• For a system of particles, the center of mass is
rCM
mi ri
i
m
i
• Then
i
MrCM mi ri
MaCM
i
d mi ri
i 2
dt
2
d ri
mi 2
dt
i
2
mi ri
i
M
2
d rCM d ( MrCM )
M
2
dt
dt 2
2
mi ai
i
Fi
i
Newton’s Second Law for a system of
particles
• From the previous slide:
MaCM Fi
i
• Here Fi is a resultant force on particle i
• According to the Newton’s Third Law, the forces that
particles of the system exert on each other (internal
forces) should cancel:
MaCM Fnet
• Here Fnet is the net force of all external forces that
act on the system (assuming the mass of the system
does not change)
Newton’s Second Law for a system of
particles
MaCM Fnet
Linear momentum for a system of
particles
• We define a total momentum of a system as:
P pi mi vi
i
i
• Using the definition of the center of mass
dri
P mi vi mi
dt
i
i
d mi ri
i
dt
drCM
M
dt
MvCM
• The linear momentum of a system of particles is
equal to the product of the total mass of the system
m
r
m
r
and the velocity of the center of mass
ii ii
rCM
i
m
i
i
i
M
Linear momentum for a system of
particles
• Total momentum of a system:
P MvCM
• Taking a time derivative
dvCM
dP
MaCM Fnet
M
dt
dt
• Alternative form of the Newton’s Second Law for a
system of particles
dP
Fnet
dt
Conservation of linear momentum
• From the Newton’s Second Law
dP
Fnet
dt
• If the net force acting on a system is zero, then
dP
0
dt
P const
• If no net external force acts on a system of particles,
the total linear momentum of the system is conserved
(constant)
• This rule applies independently to all components
Fnet , x 0 Px const
Center of mass of a rigid body
• For a system of individual particles we have
rCM
mi ri
i
m
i
i
• For a rigid body (continuous assembly of matter)
with volume V and density ρ(V) we generalize a
definition of a center of mass:
rCM
volume
r dV
volume
dV
r dm
M
Chapter 9
Problem 37
A uniform piece of steel sheet is shaped as shown. Compute the x and y
coordinates of the center of mass of the piece.
Impulse
• During a collision, an object is acted upon by a
force exerted on it by other objects participating in
the collision
dp
Fnet (t )
dt
dp Fnet (t )dt
tf
ti
tf
dp Fnet (t )dt
• We define impulse as:
tf
I Fnet (t )dt
ti
• Then (momentum-impulse theorem)
p f pi I
ti
Elastic and inelastic collisions
• During a collision, the total linear momentum is always
conserved if the system is isolated (no external force)
• It may not necessarily apply to the total kinetic energy
• If the total kinetic energy is conserved during the
collision, then such a collision is called elastic
• If the total kinetic energy is not conserved during the
collision, then such a collision is called inelastic
• If the total kinetic energy loss during the collision is a
maximum (the objects stick together), then such a
collision is called perfectly inelastic
Elastic collision in 1D
K const
2
2
m1v12i m2 v22i m1v1 f m2 v2 f
2
2
2
2
m1 (v1i v1 f )(v1i v1 f )
m2 (v2i v2 f )(v2i v2 f )
(m1 m2 )
2m2
v1 f
v1i
v2 i
(m1 m2 )
(m1 m2 )
v2 f
2m1
(m2 m1 )
v1i
v2 i
(m1 m2 )
(m1 m2 )
P const
m1v1i m2 v2i m1v1 f m2 v2 f
m1 (v1i v1 f ) m2 (v2i v2 f )
Elastic collision in 1D: stationary target
(m1 m2 )
2m2
v1 f
v1i
v2 i
(m1 m2 )
(m1 m2 )
2m1
(m2 m1 )
v2 f
v1i
v2 i
(m1 m2 )
(m1 m2 )
• Stationary target: v2i = 0
• Then
(m1 m2 )
v1 f
v1i
(m1 m2 )
2m1
v2 f
v1i
(m1 m2 )
Chapter 9
Problem 18
A bullet of mass m and speed v passes completely through a pendulum bob of
mass M. The bullet emerges with a speed of v/2. The pendulum bob is
suspended by a stiff rod of length l and negligible mass. What is the minimum
value of v such that the pendulum bob will barely swing through a complete
vertical circle?
Perfectly inelastic collision in 1D
P const
m1v1i m2 v2i (m1 m2 )v f
m1v1i m2 v2i
vf
m1 m2
Collisions in 2D
P const
Px const
Py const
Chapter 9
Problem 57
A bullet of mass m is fired into a block of mass M initially at rest at the edge of
a frictionless table of height h. The bullet remains in the block, and after impact
the block lands a distance d from the bottom of the table. Determine the initial
speed of the bullet.
Answers to the even-numbered problems
Chapter 9
Problem 8
1.39 kg⋅m/s upward
Answers to the even-numbered problems
Chapter 9
Problem 16
(a) 2.50 m/s;
(b) 3.75 × 104 J
Answers to the even-numbered problems
Chapter 9
Problem 20
(a) 4.85 m/s;
(b) 8.41 m
Answers to the even-numbered problems
Chapter 9
Problem 22
7.94 cm
Answers to the even-numbered problems
Chapter 9
Problem 58
(a) – 0.667 m/s;
(b) 0.952 m