Chapter 9 Linear Momentum and Collisions. Conservation Laws in Nature: Why do objects move at...
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Transcript of Chapter 9 Linear Momentum and Collisions. Conservation Laws in Nature: Why do objects move at...
![Page 1: Chapter 9 Linear Momentum and Collisions. Conservation Laws in Nature: Why do objects move at constant velocity if no force acts on them? What keeps a.](https://reader034.fdocuments.us/reader034/viewer/2022051619/56649e5f5503460f94b5914e/html5/thumbnails/1.jpg)
Chapter 9
Linear Momentum and Collisions
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Conservation Laws in Nature:
Why do objects move at constant velocity if no force acts on them?
What keeps a planet rotating and orbiting the Sun?
Where do objects get their energy? You should know this!
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Conservation of Momentum =we explore in this chapter.Definition : p=mv momentum = mass x velocity hence F=dp/dt why? (as originally stated by Newton
The total momentum of interacting objects cannot change unless an external force is acting on them
Interacting objects exchange momentum through equal and opposite forces
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What keeps a planet rotating and orbiting the Sun?
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Answer” Conservation of Angular Momentumwe will explore later rotation chap 10 and AM in chap 11Definition:
The angular momentum of an object cannot change unless an external twisting force (torque) is acting on it
Earth experiences no twisting force as it orbits the Sun, so its rotation and orbit will continue indefinitely
|angular momentum| = radius x mass x velocityActually L = r X p..a vector cross product!
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Angular momentum conservation also explains why objectsrotate faster as they shrink in radius:
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Demonstration films
Momentum conservation
Conservation of Angular Momentum
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Linear Momentum
The linear momentum of a particle, or an object that can be modeled as a particle, of mass m moving with a velocity is defined to be the product of the mass and velocity:
The terms momentum and linear momentum will be used interchangeably in the text
v
mp v
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Newton and Momentum
Newton’s Second Law can be used to relate the momentum of a particle to the resultant force acting on it
with constant mass
d md dm m
dt dt dt
vv pF a
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Thought Question:
A compact car and a Mack truck have a head-on collision. Are the following true or
false?
1. The force of the car on the truck is equal and opposite to the force of the truck on the car.
2. The momentum transferred from the truck to the car is equal and opposite to the momentum transferred from the car to the truck.
3. The change of velocity of the car is the same as the change of velocity of the truck.
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Thought Question:
A compact car and a Mack truck have a head-on collision. Are the following true or false?
1. The force of the car on the truck is equal and opposite to the force of the truck on the car. T
2. The momentum transferred from the truck to the car is equal and opposite to the momentum transferred from the car to the truck. T
3. The change of velocity of the car is the same as the change of velocity of the truck. F
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Newton’s Second Law
The time rate of change of the linear momentum of a particle is equal to the net force acting on the particle This is the form in which Newton presented the
Second Law It is a more general form than the one we used
previously This form also allows for mass changes
Applications to systems of particles are particularly powerful
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Conservation of Linear Momentum
Whenever two or more particles in an isolated system interact, the total momentum of the system remains constant The momentum of the system is conserved, not
necessarily the momentum of an individual particle
This also tells us that the total momentum of an isolated system equals its initial momentum
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Conservation of Momentum, 2
Conservation of momentum can be expressed mathematically in various ways
In component form, the total momenta in each direction are independently conserved pix = pfx piy = pfy piz = pfz
Conservation of momentum can be applied to systems with any number of particles
This law is the mathematical representation of the momentum version of the isolated system model
total 1 2p = p + p = constant
1i 2i 1f 2fp + p = p + p
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Conservation of Momentum, Archer Example
The archer is standing on a frictionless surface (ice)
Approaches: Newton’s Second Law –
no, no information about F or a
Energy approach – no, no information about work or energy
Momentum – yes
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Archer Example, 2
Conceptualize The arrow is fired one way and the archer recoils in the
opposite direction Categorize
Momentum Let the system be the archer with bow (particle 1) and the
arrow (particle 2) There are no external forces in the x-direction, so it is
isolated in terms of momentum in the x-direction Analyze
Total momentum before releasing the arrow is 0
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Archer Example, 3
Analyze, cont. The total momentum after releasing the arrow is
Finalize The final velocity of the archer is negative
Indicates he moves in a direction opposite the arrow Archer has much higher mass than arrow, so velocity
is much lower
1 2 0f f p p
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Perfectly Inelastic Collisions
Since the objects stick together, they share the same velocity after the collision
1 1 2 2 1 2i i fm m m m v v v
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Elastic Collisions
Both momentum and kinetic energy are conserved
1 1 2 2
1 1 2 2
2 21 1 2 2
2 21 1 2 2
1 1
2 21 1
2 2
i i
f f
i i
f f
m m
m m
m m
m m
v v
v v
v v
v v
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Collision Example – Ballistic Pendulum Conceptualize
Observe diagram Categorize
Isolated system of projectile and block
Perfectly inelastic collision – the bullet is embedded in the block of wood
Momentum equation will have two unknowns
Use conservation of energy from the pendulum to find the velocity just after the collision
Then you can find the speed of the bullet
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Center of Mass, Coordinates
The coordinates of the center of mass are
M is the total mass of the system Use the active figure to
observe effect of different masses and positions
CM
CM
CM
i ii
i ii
i ii
m xx
Mm y
yMm z
zM
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Center of Mass, Extended Object
Similar analysis can be done for an extended object
Consider the extended object as a system containing a large number of particles
Since particle separation is very small, it can be considered to have a constant mass distribution
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Center of Mass, position
The center of mass in three dimensions can be located by its position vector, For a system of particles,
is the position of the ith particle, defined by
For an extended object, CM
1dm
M r r
ˆ ˆ ˆi i i ix y z r i j k
CMr
1CM i i
i
mM
r r
ir
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Center of Mass, Symmetric Object
The center of mass of any symmetric object lies on an axis of symmetry and on any plane of symmetry If the object has uniform density
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Finding Center of Mass, Irregularly Shaped Object
Suspend the object from one point
The suspend from another point
The intersection of the resulting lines is the center of mass
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Center of Gravity
Each small mass element of an extended object is acted upon by the gravitational force
The net effect of all these forces is equivalent to the effect of a single force acting through a point called the center of gravity If is constant over the mass distribution, the
center of gravity coincides with the center of mass
Mg
g
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Rocket Propulsion, 2
The initial mass of the rocket plus all its fuel is M + m at time ti and speed v
The initial momentum of the system is
i = (M + m) p v
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Rocket Propulsion, 3
At some time t + t, the rocket’s mass has been reduced to M and an amount of fuel, m has been ejected
The rocket’s speed has increased by v
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Rocket Propulsion, 4
Because the gases are given some momentum when they are ejected out of the engine, the rocket receives a compensating momentum in the opposite direction
Therefore, the rocket is accelerated as a result of the “push” from the exhaust gases
In free space, the center of mass of the system (rocket plus expelled gases) moves uniformly, independent of the propulsion process
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Rocket Propulsion, 5
The basic equation for rocket propulsion is
The increase in rocket speed is proportional to the speed of the escape gases (ve) So, the exhaust speed should be very high
The increase in rocket speed is also proportional to the natural log of the ratio Mi/Mf
So, the ratio should be as high as possible, meaning the mass of the rocket should be as small as possible and it should carry as much fuel as possible
ln if i e
f
Mv v v
M
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Thrust
The thrust on the rocket is the force exerted on it by the ejected exhaust gases
The thrust increases as the exhaust speed increases
The thrust increases as the rate of change of mass increases The rate of change of the mass is called the burn rate
e
dv dMthrust M v
dt dt