Physics 1000 - Newton's Laws of Motion PDF

Summary

These lecture notes cover Newton's Laws of Motion, including inertia, force, equilibrium, and friction, offering a foundational physics overview. Examples and explanations are included and the document also includes several checkpoint questions for active learning.

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Physics 1000 –
001/002
Newton’s Laws of Motion
 Inertia

The property of objects to resist changes in
motion
 Newton’s 1st Law of Motion

Every object continues in a state of rest or a
state of uniform motion in a straight line unless
acted on by net external force
 Force

Force
In the simplest sense, a force is a push or a pull

Net Force
The vector sum of forces that act on an object
 Equilibrium
Mechanical Equilibrium
The state of an object when the net force acting on it is zero
When an object is at rest, it is in static equilibrium
When an object is moving at a constant velocity, the net force acting on it is still zero
(there is no change in velocity)
The object is still in mechanical equilibrium, but we call this dynamic equilibrium

Equilibrium Rule

The vector sum of the forces equals zero
 Checkpoint Question

A jet cruises at a constant velocity of 1000 km/h when the thrusting force of
its engines is a constant 100,000 N.
What is the acceleration of the jet?

What is the force of air resistance on the jet?
 Friction

The resistive force that opposes the motion or attempted motion of an
object either past another object with which it is in contact or through a fluid
Static Friction
Friction between objects that are not moving relative to each other
Kinetic friction (aka sliding friction)
Friction between objects moving relative to each other
Static friction is typically higher than kinetic (sliding) friction
This means it takes more force to get an object moving that to simply keep it moving
 Checkpoint Questions
Marie exerts a 100 N horizontal force on a table on the floor, and it doesn’t slide. This
indicated that 100 N isn’t great enough to make the table slide.
How does the friction force between the table and the floor compare with Marie’s push?

She then pushes with an extra 10 N, and the table still doesn’t slide.
How much friction acts on the table?

She pushes even harder, and the table moves. Once in motion she finds that a push of 115 N
is enough to keep the table sliding at a constant velocity.
How much friction then acts on the table?
What net force acts on the sliding table when pushed with 125 N which the friction with the floor is 115 N?

In the above cases, when does static friction occur, when does sliding friction occur, and
when does no friction occur?
 Vector Terminology
Vector Quantity
A quantity that has both magnitude and direction

Vector
The arrow used to represent a vector quantity

Scalar Quantity
A quantity that has magnitude but not direction

Resultant
The net result of a combination of two or more vectors
 Newton’s 2nd Law of Motion

The acceleration of an object is directly proportional
to the net force acting on the object, is in the
direction of the net force, and is inversely
proportional to the mass of the object
 Newton’s 2nd Law of Motion

Written as an equation, Newton’s second law looks like:
Acceleration = Net Force / Mass
As an equation,

If we multiply both sides by mass, we get the more commonly seen:
 Mass and Weight
These are commonly used interchangeably, but are distinct in physics
Mass is the quantity of matter in an object
Mass is also the measure of an object’s inertia

Weight is a force, usually due to gravity
For constant gravity, weight and mass are proportional
This is why they are commonly used interchangeably in everyday life
As an example, gravity on the Moon is about 1/6 as strong as on Earth, so objects only weigh 1/6 as
much, while still having the same mass

SI Units
kilogram (kg) for mass
Newton (N) for weight, as it is a force
 Checkpoint Questions
Does a 2 kg iron block possess twice as much inertia as a 1 kg iron block? Twice
as much mass? Twice as much volume? Twice as much weight?
Does a 2 kg iron block possess twice as much inertia as a 1 kg bunch of bananas?
Twice as much mass? Twice as much volume? Twice as much weight?
How does the mass of a bar of gold vary with location?
If you were a passenger on the International Space Station and were confronted
with two cans, one fills with beans and the other empty, how would you
determine which is full and which is empty?
In which case would it be easier to lift a cement truck: on Earth’s surface or on
the Moon’s surface?
 Units of Force

The SI unit of force is the Newton (N), but how is a Newton related to the
other units?
We know that:
Using dimensional analysis:
So
 Checkpoint Questions

In Chapter 2, acceleration was defined as the change in velocity over time.
Are we saying in this chapter that acceleration is instead the ratio of force to
mass, F/m? Which is it?
What three controls in an automobile allow the driver to produce
acceleration? How does the automobile’s mass affect the acceleration?
In a vacuum, a coin and a feather fall at the same rate, side by side.
Would it be correct to say that equal forces of gravity act on both the coin and the
feather when in a vacuum?
 Force Types
Contact Force
Any force that occurs as a result of two objects making contact with each other

Normal Force
A component of a contact force that is perpendicular to the surface in contact
In resting objects, is also knows as support force

Support Force
An upward force opposite to the force of gravity
This force comes from the supporting object wanting to keep its shape
Friction as a Component of a Contact Force
 Non-Free Fall
When objects fall on Earth in real life, they aren’t falling in a vacuum, so they
don’t act as in free fall
This is because air resistance (drag) resists the gravitational force, a form of
friction
Written as an equation,
Unless R=0, acceleration will be less than gravitational acceleration

Air resistance depends on two things, both of which cause the object to have to
move through more air molecules, which is what actually creates the drag
Frontal surface area of the falling object
The speed of the falling object
 Terminal Velocity
Air resistance will continue to increase until it completely
counteracts gravity, and equilibrium is reached
When this occurs, an object has reached its terminal speed
When combined with direction, we say that the object has
reached terminal velocity
Increasing frontal surface area is the primary way of
decreasing terminal velocity
This is what makes parachutes effective at creating a safe terminal
velocity
 Problem #1
What is the acceleration produced by a net force of 2000 N exerted on a
1000 kg car?
 Problem #1
What is the acceleration produced by a net force of 2000 N exerted on a
1000 kg car?
 Problem #1
What is the acceleration produced by a net force of 2000 N exerted on a
1000 kg car?
 Problem #1
What is the acceleration produced by a net force of 2000 N exerted on a
1000 kg car?
 Problem #2
Find the amount of force, or thrust, on a 20,000 kg jet plane to achieve an
acceleration of
 Problem #2
Find the amount of force, or thrust, on a 20,000 kg jet plane to achieve an
acceleration of
 Problem #2
Find the amount of force, or thrust, on a 20,000 kg jet plane to achieve an
acceleration of
 Problem #2
Find the amount of force, or thrust, on a 20,000 kg jet plane to achieve an
acceleration of
 Problem #2
Find the amount of force, or thrust, on a 20,000 kg jet plane to achieve an
acceleration of
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Problem #3
Consider a problem expressed in symbols only:
A force F acts in a forward direction on a carton of doughnuts of mass m, which a
friction force f opposes the motion. Find the acceleration of the carton.
Then, express this in numbers is the mass of the carton is 4.0 kg and the applied force is
12.0 N against a friction force of 6.0 N.
 Force as an Interaction
Previously, we defined a force simply as a push or a pull
More accurately, a force is part of an interaction between one thing and
another
These interactions actually happen in pairs, with both objects exerting a
force on the other
Pair of forces

Even when it may seem like only one object is exerting a force on another
object, it is actually a pair of forces
These pairs of forces are treated as one interaction
 Examples of Pairs of Forces
Pushing on a wall
The wall pushes back, keeping you from falling over

A boxer hitting a punching bag
The bag exerts a force on the glove, which is what stops its motion

A hammer hitting a nail
The nail stops the motion of the hammer

Other examples previously mentioned
Normal force
Static Friction force
 Checkpoint Questions

Is it possible to push on something without that same something pushing
back on you?
 Checkpoint Questions

Does a high-speed baseball possess force?
 Newton’s 3rd Law of Motion

Whenever one object exerts a force on a second
object, the second object simultaneously exerts an
equal and opposite force on the first.
 Newton’s 3rd Law of Motion

If we consider one force the action force and the other the
reaction force, we can rephrase Newton’s third law to:

To every action there is always an opposed equal reaction.
 Identifying Action and Reaction

When trying to determine the force pair of an interaction, identify the
action, then the reaction.

Action: Object A exerts a force on object B.
Reaction: Object B exerts a force on object A.
 Internal vs External Forces

If force pairs are equal and opposite, why don’t they just cancel out?
It depends on your reference frame

For a system to accelerate, the external net force needs to be nonzero

Interactions that happen completely within a system are called internal
 Checkpoint Questions

On a cold, rainy day, you find yourself in a car with a dead battery.
You must
push the car to move it and get it started. Why can’t you move the car by
remaining comfortably inside and pushing against the dashboard?
 Checkpoint Questions

A car accelerates along a road. Identify the force that moves the car.
 Action and Reaction on Different Masses

While the forces in an interaction are the same, differences in mass can
create different magnitudes of acceleration

If one object is more massive that the second object, it will undergo less
acceleration than the less massive object for the same force
 Homework

Read Chapter 3
Conceptual Questions: 3, 10, 14, 20, 26, 32, 38, 44, 49, 56
Exercises: 63, 68, 70, 72, 76