Physics 110 - Lecture 2 - Forces and Newton's Laws PDF

Summary

This document is a lecture on the topic of forces and Newton's laws in physics. It discusses inertia, dynamics, and equilibrium. The focus is a breakdown of the fundamentals of physics.

Full Transcript

Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 1

FORCES AND NEWTON’S
LAWS
Chapters 2,4,5
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 2

Student learning objectives
Inertia
Force
Newton's First Law of Motion
Net Force and Vectors
The Equilibrium Rule
Support Force
Equilibrium of Moving Things
Force Causes Acceleration
Friction
Mass and Weight
Newton's Second Law of Motion
Free Fall
Nonfree Fall
Newton’s Third Law of Motion
Vectors and the Third Law
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 3

Dynamics
Dynamics (the study of forces: why things move) is
essentially made up of Newton’s Three Laws of motion.
The textbook divides these up into three chapters (2,4,5),
but we’re going to compress them into one lecture.
We should probably start with “What is a force?”
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 4

Inertia
Objects of different weight fall to the
ground at the same rate in the
absence of air resistance.
A moving object needs no force to
keep it moving in the absence of
friction.
Inertia is a property of matter to
resist changes in motion.
It depends on the amount of matter
in an object (its mass).
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 5

Forces
A force is any push or pull between two objects.
Notice that there must be two objects involved
Some examples:
Gravitational force (weight) – your book is very sloppy
with this terminology. For us, the force of gravity will be
synonymous with weight
Tension – in ropes and strings and wires
Normal force – your book calls this “support force”; it’s the
force that a surface exerts to keep you from sinking into it
Friction – acts opposite to relative motion due to surfaces
Buoyant force – upward force in fluids
Electric force
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 6

Forces
Forces are vectors, since they have a magnitude and a
direction.
The SI unit of force is the Newton (N) (in Imperial units,
it’s the pound (lb.))
When there are many forces acting on an object, we are
usually interested in the total or net force, which is the
(vector) sum of all the forces.
⃗
I’ll call the net force Σ𝐹𝐹
𝐹𝐹
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 7

Net Force
Since it’s a vector
sum, the net force
depends on the
magnitudes and
directions of the
applied forces.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 8

Equilibrium
When the net force on an object is zero
⃗𝐹𝐹 = 0), we say that the object is in
(Σ𝐹𝐹
equilibrium (more specifically,
mechanical equilibrium).
Things that are in mechanical
equilibrium have no change in their
motion.
An unbalanced (nonzero net) force
would be needed to change their state
of motion
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 9

Equilibrium
When the girl holds the
rock with as much force
upward as gravity pulls
downward, the net force
on the rock is zero.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 10

Equilibrium
The upward tension in the string
has the same magnitude as the
weight of the bag, so the net
force on the bag is zero.
The bag of sugar is attracted to
Earth with a gravitational force
of 2 pounds or 9 Newtons.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 11

Equilibrium
Two forces act on the bag
Tension force in string acts upward.
Force due to gravity acts downward.

Both are equal in magnitude and opposite
in direction.
When added, they cancel to zero.
So, the bag remains at rest.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 12

Vectors vs. Scalars
Remember the difference!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 13

Equilibrium
The scaffold is suspended by two ropes attached to its left
and right end. A painter stands at the left end of the
scaffold, to the left of the rope. Another painter stands at
the right end, just right of center, and is moving
towards the left..
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 14

Equilibrium
The sum of the upward vectors equals the sum of the
⃗𝐹𝐹 = 0, and the scaffold is in
downward vectors. Σ𝐹𝐹
equilibrium.
Two upward force vectors are drawn
along the ropes, with a longer one
on the left and shorter one on the
right.
Three downward force vectors are
drawn, one at each painter and one
at the center of the scaffold.
F(upwards) = F(downwards)
⃗𝐹𝐹 = 0
Σ𝐹𝐹
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 15

Normal (Support) Forces
In physics, the word “normal” means “perpendicular”, so
the normal force of a surface on an object is the force the
surface exerts perpendicular to that surface.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 16

Quick Question
When you stand on two bathroom
scales with one foot on each scale
and with your weight evenly
distributed, each scale will read
A. your weight.
B. half your weight.
C. zero.
D. more than your weight.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 17

Quick Question
When you stand on two bathroom scales
with one foot on each scale and with your
weight evenly distributed, each scale will
read
A. your weight.
B. half your weight.
C. zero.
D. more than your weight.

⃗𝐹𝐹 = 0
You are at rest, so Σ𝐹𝐹
The sum of the two upward support
forces is equal to your weight.
Your weight is distributed over the two
scales. So, each scale reads half your
weight.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 18

Quick Question
If the gymnast hangs with her
weight evenly divided between
the two rings, how would scale
readings in both supporting
ropes compare with her weight?
Suppose she hangs with slightly
more of her weight supported by
the left ring. How would a scale
on the right read?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 19

Quick Question
If the gymnast hangs with her
weight evenly divided between
the two rings, how would scale
readings in both supporting
ropes compare with her weight?
Each half
Suppose she hangs with slightly
more of her weight supported by
the left ring. How would a scale
on the right read? Less than
half
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 20

Equilibrium
So far, we’ve looked at static equilibrium, where the
object of interest is at rest.
⃗ = 0, since nothing is moving.
It’s clear in that case that Σ𝐹𝐹
𝐹𝐹
However, we may also have dynamic equilibrium, where
an object is moving at constant speed in a straight line.
This type of motion is also called rectilinear motion, and it
means once again that Σ𝐹𝐹 ⃗𝐹𝐹 = 0.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 21

Equilibrium
Equilibrium test: whether something undergoes
change in motion
Static equilibrium: A crate at rest (no change in motion).
Dynamic equilibrium: A crate pushed at steady speed
(no change in motion).
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 22

Quick Question
An airplane flies horizontally at constant speed in a
straight-line direction. Its state of motion is unchanging. In
other words, it is in equilibrium. Two horizontal forces act
on the plane. One is the thrust of the propeller that pulls it
forward. The other is the force of air resistance (air
friction) that acts in the opposite direction. Which force is
greater?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 23

Quick Question
An airplane flies horizontally at constant speed in a
straight-line direction. Its state of motion is unchanging. In
other words, it is in equilibrium. Two horizontal forces act
on the plane. One is the thrust of the propeller that pulls it
forward. The other is the force of air resistance (air
friction) that acts in the opposite direction. Which force is
greater?

They are the same!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 24

Friction
Depends on the kinds of material
and how much they are pressed
together.
Is due to tiny surface bumps and to
"stickiness" of the atoms on a
material's surface.
Example: Friction between a crate on
a smooth wooden floor is less than
that on a rough floor.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 25

Friction
Surfaces can also exert forces parallel to the surface
(remember that normal forces are perpendicular).
These forces are frictional forces. They come in two
types, static friction and kinetic (or dynamic) friction.
Static friction exists before an object moves to oppose
another force, while kinetic exists when an object is
sliding.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 26

Quick Question
You push a crate at a steady
speed in a straight line. If the
friction force is 75 N, how much
force must you apply?
A. More than 75 N.
B. Less than 75 N.
C. Equal to 75 N.
D. Not enough information.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 27

Quick Question
You push a crate at a steady speed in a
straight line. If the friction force is 75 N, how
much force must you apply?
A. More than 75 N.
B. Less than 75 N.
C. Equal to 75 N.
D. Not enough information.

The crate is in dynamic equilibrium. So
there is no NET force acting on it.
So you must apply a force that balances out
the force of friction.
Applied force must be equal and opposite to
the force of friction.

So if Friction is 75 N to the left, the Applied
Force from you is 75 N to the right.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 28

Dynamic Equilibrium
When the push on the
desk is the same as
the force of friction
between the desk and
the floor, the net force
is zero and the desk
slides at an
unchanging speed.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 29

Quick Question
You are riding in a vehicle at a steady
speed and toss a coin straight
upward. Where will the coin land?
A. Behind you.
B. Ahead of you.
C. In your hand.
D. There is not enough information.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 30

Quick Question
You are riding in a vehicle at a steady
speed and toss a coin straight
upward. Where will the coin land?
A. Behind you.
B. Ahead of you.
C. In your hand.
D. There is not enough information.

Due to the coin's inertia, it continues
sideways with the same speed as
the vehicle in its up-and-down
motion, which is why it lands in your
hand.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 31

Newton’s 1st Law
So here it is, Newton’s 1st Law of Motion:

An object in equilibrium (static or dynamic) will remain in
equilibrium unless the net force on the object differs from
zero.

You may have heard other similar version, like “An object
at rest remains at rest unless acted upon by an outside
force”, but remember this holds for dynamic equilibrium
too!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 32

Free Body Diagrams
When examining forces, it is convenient to make free
body diagrams (FBDs), which is a diagram for a given
mass that has all forces acting on it labelled with the
correct directions.
While a picture of the object is nice, forces do not care
about the shape or size of the object, so a dot or box will
suffice.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 33

FBDs
a) The tension in the rope
is 300 N, equal to
Nellie’s weight.
b) The tension in each
rope is now 150 N, half
of Nellie’s weight. In
each case,Σ𝐹𝐹⃗𝐹𝐹 = 0.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 34

Vectors
Remember that if the forces are not pointing in the same
direction, we need to add them as vectors, which might
mean using components!
To add graphically, remember the parallelogram rule:
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 35

FBDs and Vectors
Nellie’s weight is shown by the downward vertical vector.
An equal and opposite vector is needed for equilibrium, shown
by the dashed vector. Note that the dashed vector is the
diagonal of the parallelogram defined by the dotted lines.
Using the parallelogram rule, we find that the tension in each
rope is more than half her weight.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 36

FBDs and Vectors
As the angle between the ropes increases, tension
increases so that the resultant (dashed-line vector)
remains at 300 N upward, which is required to support
300-N Nellie.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 37

FBDs and Vectors
When the ropes supporting Nellie are at different angles
to the vertical, the tensions in the two ropes are unequal.
By the parallelogram rule, we see that the right rope bears
most of the load and has the greater tension.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 38

FBDs and Vectors
You can safely hang from a clothesline hanging vertically,
but you will break the clothesline if it is strung horizontally.

This is also how you can get your car out of the mud!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 39

Quick Question
Two sets of swings
are shown at right.
If the children on the
swings are of equal
weights, the ropes of
which swing are more
likely to break?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 40

Quick Question
Two sets of swings
are shown at right.
If the children on the
swings are of equal
weights, the ropes of
which swing are more
likely to break?

Girl on right
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 41

Inertia
Newton’s 1st Law (NL1) is also called the “Law of Inertia”.
Inertia is a tendency for an object to keep doing what it’s
doing.
The quantity we use to measure inertia is the object’s
mass (measured in kilograms).
The more mass an object has, the harder it is to change
its motion
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 42

Mass
Mass: The quantity of matter in an object. It is also the
measure of the inertia
Inertia is resistance to change in motion
Greater Inertia = Greater Mass

The pillow has a larger size (volume) but a smaller mass
than the battery.
Note that volume is the amount
of space an object takes up,
not how much mass it has.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 43

Mass vs. Weight
Also, be sure not to confuse mass with weight.
Weight is the gravitational force on an object (in deep
space, your weight would be zero)
Standard unit of force is the newton (N)

Mass is the amount of stuff inside an object, and doesn’t
depend on the local gravitational field.
Unit of measurement is the kilogram (kg)
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 44

Mass vs. Weight
One way to measure
mass is to shake an
object back and forth
(this is how astronauts
“weigh” themselves in
space).
It’s just as difficult to
shake a stone in its
weightless state in space
as it is in its weighted
state on Earth.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 45

Mass vs. Weight
One kilogram of mass weighs 10 Newtons on Earth.
If you prefer, a kilogram weighs 2.2 pounds on Earth
The Imperial unit for mass is the stone, which weighs 14
pounds (I told you these units were stupid!)
If we want to calculate the gravitational force at other
locations, we use 𝑔𝑔𝐹𝐹𝑔𝑔 = 𝑚𝑚𝑚𝑚𝑚𝑚𝑚𝑚,where 𝑚𝑚
𝑚𝑚is the gravitational
acceleration at that location.
So weight and mass are proportional, but weight depends
on the gravitational field strength!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 46

Quick Question
Does a 2-kilogram bunch of bananas have twice as much
inertia as a 1-kilogram loaf of bread?
Twice as much mass?
Twice as much volume?
Twice as much weight, when weighed in the same
location?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 47

Quick Question
Does a 2-kilogram bunch of bananas have twice as much
inertia as a 1-kilogram loaf of bread? Yes
Twice as much mass? Yes
Twice as much volume? No
Twice as much weight, when weighed in the same
location? Yes
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 48

Inertia = Mass
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 49

Quick Question
When the string is pulled down slowly,
the top string breaks, which best
illustrates the
A. weight of the ball.
B. mass of the ball.
C. volume of the ball.
D. density of the ball.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 50

Quick Question
When the string is pulled down slowly,
the top string breaks, which best
illustrates the
A. weight of the ball.
B. mass of the ball.
C. volume of the ball.
D. density of the ball
The tension in the top string is the
pulling tension in the bottom string plus
the weight of the ball. So, the top string
has greater tension and breaks first.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 51

Newton’s 2nd Law
What if the net force is not zero (meaning the system is
not in mechanical equilibrium)?
Newton’s 2nd Law says
⃗𝐹𝐹 = 𝑚𝑚𝑎𝑎
Σ𝐹𝐹 ⃗
𝑎𝑎
Here 𝑚𝑚 is the mass and 𝑎𝑎
⃗ is the resulting acceleration.
So this is the connection between kinematics and
dynamics: forces cause accelerations
Acceleration is inversely proportional to mass.
1
Acceleration ∼
mass
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 52

Newton’s 2nd Law
This also means the acceleration is
equal to the net force divided by the
mass.
If the net force acting on an object
doubles, its acceleration is doubled.
If the mass is doubled, then acceleration
will be halved.
If both the net force and the mass are
doubled, the acceleration will be
unchanged.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 53

Newton's second law of motion
Newton's second law relates acceleration, force and
mass:
The acceleration produced by a net force on an object is
directly proportional to the net force, is in the same direction
as the net force, and is inversely proportional to the mass of
the object.
In equation form: Acceleration = net force
mass
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 54

Quick Question
If a car can accelerate at 2 m/s2, what acceleration can it
attain if it is towing another car of equal mass?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 55

Quick Question
If a car can accelerate at 2 m/s2, what acceleration can it
attain if it is towing another car of equal mass?

1 m/s2

Explanation

F = ma
a = F/m = 2 m/s2
But now m = 2m
a = F/2m = 2 /2 = 1 m/s2
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 56

Quick Question
How much force, or thrust, must a 30,000-kg jet plane
develop to achieve an acceleration of 1.5 m/s2?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 57

Quick Question
How much force, or thrust, must a 30,000-kg jet plane
develop to achieve an acceleration of 1.5 m/s2?

45 kN

F = ma
F = (30,000)(1.5) = 45,000N
F = 45 kN
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 58

Newton's second law of motion
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 59

Free Fall
Now we can explain why
(in the absence of air
resistance) all masses
fall at the same rate.
Even though the force of
gravity is larger for a
larger mass, its mass is
also larger by the same
factor, so the
acceleration (which is
the ratio 𝐹𝐹𝐹𝐹/𝑚𝑚𝑚𝑚) is the
same!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 60

Quick Question
A cart is pushed and undergoes a certain acceleration. Consider how
the acceleration would compare if it were pushed with twice the net
force while its mass increased by four. Then its acceleration would be
A. one quarter.
B. half.
C. twice.
D. the same.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 61

Quick Question
A cart is pushed and undergoes a certain acceleration. Consider how
the acceleration would compare if it were pushed with twice the net
force while its mass increased by four. Then its acceleration would be
A. one quarter.
B. half.
C. twice.
D. the same.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 62

Quick Question
A 5-kg iron ball and a 10-kg iron ball are dropped from rest.
For negligible air resistance, the acceleration of the heavier
ball will be
A. less.
B. the same.
C. more.
D. undetermined.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 63

Quick Question
A 5-kg iron ball and a 10-kg iron ball are dropped from rest.
For negligible air resistance, the acceleration of the heavier
ball will be
A. less.
B. the same.
C. more.
D. undetermined.

Both are in "free fall." Hence their equal acceleration
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 64

Quick Question
A 5-kg iron ball and a 10-kg iron ball are dropped from rest.
When the free-falling 5-kg ball reaches a speed of 10 m/s,
the speed of the free-falling 10-kg ball is
A. less than 10 m/s.
B. 10 m/s.
C. more than 10 m/s.
D. undetermined.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 65

Quick Question
A 5-kg iron ball and a 10-kg iron ball are dropped from rest.
When the free-falling 5-kg ball reaches a speed of 10 m/s,
the speed of the free-falling 10-kg ball is
A. less than 10 m/s.
B. 10 m/s.
C. more than 10 m/s.
D. undetermined.

Both are in "free fall." Hence their equal speeds.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 66

Nonfree Fall
When an object falls downward through the air it
experiences
force of gravity pulling it downward.
air drag force acting upward.

The condition of nonfree fall
occurs when air resistance is nonnegligible.
depends on two things:
 speed and
 frontal surface area.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 67

Nonfree fall
When the object is moving fast enough so that air
resistance builds up to balance the force of gravity.
Then no net force
No acceleration
Velocity does not change
Terminal velocity
when air resistance balances weight, net force is zero
occurs when acceleration terminates
refers to terminal speed along with the direction of motion, which is
downward.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 68

Air Resistance
If there is drag, the acceleration will not
be a constant 𝑚𝑚𝑚𝑚.
Drag is proportional to the speed of an
object: the faster it goes, the greater the
drag force.
So the acceleration of a falling object
would start at 𝑚𝑚
, but would drop off to
𝑚𝑚
zero as the object speeds up.
When the acceleration finally reaches
zero (so that the weight and the drag
force have equal magnitude), the
velocity the object has is called the
terminal velocity.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 69

Skydiver in fall after jumping from a plane.

Weight and air resistance act on the falling
object.
As falling speed increases, air resistance on
diver builds up, net force is reduced, and
acceleration is reduced.
When air resistance equals the diver's
weight, net force is zero and acceleration
terminates.
Diver reaches terminal velocity, then
continues the fall at constant speed.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 70

Quick Question
When a 20-N falling object encounters 5 N of air
resistance, its acceleration of fall is
A. less than g.
B. more than g.
C. g.
D. terminated.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 71

Quick Question
When a 20-N falling object encounters 5 N of air
resistance, its acceleration of fall is
A. less than g.
B. more than g.
C. g.
D. terminated.

Acceleration of a nonfree fall is always less than g.
Acceleration will actually be
(20N − 5 N)/2 kg = 7.5 m/s2.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 72

Quick Question
Consider a heavy and a light person jumping together with
same-size parachutes from the same altitude. Who will
reach the ground first?
A. The light person
B. The heavy person
C. Both will reach at the same time.
D. Not enough information is provided.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 73

Quick Question
Consider a heavy and a light person jumping together with
same-size parachutes from the same altitude. Who will reach the
ground first?
A. The light person
B. The heavy person
C. Both will reach at the same time.
D. Not enough information is provided.

Both people feel a similar upward drag force at any given speed.
The heavier person has a greater downward weight force than
the lighter person.
Thus, the heavier person must drop farther before the upward
drag force balances the downward weight force, resulting in a
greater terminal speed.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 74

Quick Question
If the rock and the feather are dropped in a space where
the air has been removed by a vacuum pump,
A. the feather hits the bottom first, before the rock hits.
B. the rock hits the bottom first, before the feather hits.
C. the rock and the feather drop together side by side.
D. more information is needed to determine whether the
rock or the feather hits bottom first.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 75

Quick Question
If the rock and the feather are dropped in a space where
the air has been removed by a vacuum pump,
A. the feather hits the bottom first, before the rock hits.
B. the rock hits the bottom first, before the feather hits.
C. the rock and the feather drop together side by side.
D. more information is needed to determine whether the
rock or the feather hits bottom first.

There is no air, because it is vacuum. Hence no air resistance.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 80

Newton’s 3rd Law
Newton’s 3rd Law states that

To every action there is always an opposed equal
reaction.

It is important to note that these action-reaction pairs of
forces always act on different objects!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 81

Newton’s 3rd Law
The interaction that drives the nail is the same as the one
that halts the hammer.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 82

Newton’s 3rd Law
In every interaction, the forces always
occur in pairs.
You push against the floor, and the floor
simultaneously pushes against you.
The tires of a car interact with the road to
produce the car’s motion. The tires push
against the road, and the road
simultaneously pushes back on the tires.
When swimming, you push the water
backward, and the water pushes you
forward.
When the girl jumps to shore, the
boat moves backward.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 83

Action-Reaction Pairs
When action is A exerts force on B, the reaction is simply
B exerts force on A.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 84

Action-Reaction Pairs
Earth is pulled up by the boulder
with just as much force as the
boulder is pulled down by Earth.
So why doesn’t Earth “jump up” to
meet the boulder?
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Action-Reaction Pairs
Just because the forces are the same in magnitude, the
accelerations are certainly not!
Although the pair of forces between the boulder and Earth
is the same, the masses are quite unequal.
Acceleration is not only proportional to the net force, but it
is also inversely proportional to the mass.
Because Earth has a huge mass, we don’t sense its
infinitesimally small acceleration.
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Action-Reaction Pairs
The cannonball undergoes more acceleration than the
cannon because its mass is much smaller.
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Action-Reaction Pairs
F represents both the action and reaction forces; m
(large), the mass of the cannon; and m (small), the mass
of the cannonball.
Do you see why the change in the velocity of the
cannonball is greater compared with the change in
velocity of the cannon?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 88

Action-Reaction Pairs
The balloon recoils from the escaping
air and climbs upward.
If a balloon is released and allowed to
move, it accelerates as the air comes
out.
A rocket accelerates in much the same
way—it continually recoils from the
exhaust gases ejected from its engine.
Each molecule of exhaust gas acts like
a tiny molecular cannonball shot
downward from the rocket.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 89

Quick Question
A tug of war occurs between boys and girls on a polished
floor that’s somewhat slippery. If the boys are wearing
socks and the girls are wearing rubber-soled shoes, who
will surely win, and why?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 90

Quick Question
A tug of war occurs between boys and girls on a polished
floor that’s somewhat slippery. If the boys are wearing
socks and the girls are wearing rubber-soled shoes, who
will surely win, and why?

Girls
As no friction force on boys means net force is not zero
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 91

Action-Reaction Pairs
So why don’t these pairs just cancel each other out and
⃗𝐹𝐹 = 0?
produce Σ𝐹𝐹
We need to be careful about the system we are
examining.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 92

Defining Systems
A force acts on the orange, and the orange accelerates to
the right.
The dashed line surrounding the orange encloses and
defines the system.
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Defining Systems
The vector that pokes outside the dashed line represents
an external force on the system.
The system (that is, the orange) accelerates in accord
with Newton’s second law.
The force on the orange, provided by the apple, is not
cancelled by the reaction force on the apple. The orange
still accelerates.
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Defining Systems
The force is provided by an apple, which doesn’t change
our analysis. The apple is outside the system.
The fact that the orange simultaneously exerts a force on
the apple, which is external to the system, may affect the
apple (another system), but not the orange.
You can’t cancel a force on the orange with a force on the
apple. So in this case the action and reaction forces don’t
cancel.
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Defining Systems
a) Action and reaction
forces cancel.
b) When the floor
pushes on the
apple (reaction to
the apple’s push
on the floor), the
orange-apple
system
accelerates.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 96

Defining Systems
When the force pair is internal to the orange-apple system, the
forces do cancel each other. They play no role in accelerating
the system.
A force external to the system is needed for acceleration.
When the apple pushes against the floor, the floor simultaneously
pushes on the apple—an external force on the system.
The system accelerates to the right.
Inside a baseball, trillions of interatomic forces hold the ball
together but play no role in accelerating the ball. They are part
of action-reaction pairs within the ball, but they combine to
zero.
If the action-reaction forces are internal to the system, then
they cancel and the system does not accelerate.
A force external to the ball, such as a swinging bat provides, is
needed to accelerate the ball.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 97

Horse-Cart Problem
All the pairs of forces that act on the horse and cart are
shown. The acceleration of the horse-cart system is due
to the net force F – f.
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Horse-Cart Problem
Will the horse’s pull on the cart be canceled by the
opposite and equal pull by the cart on the horse, thus
making acceleration impossible?
From the farmer’s point of view, the only concern is with
the force that is exerted on the cart system.
The net force on the cart, divided by the mass of the cart, is the
acceleration.
The farmer doesn’t care about the reaction on the horse.
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Horse-Cart Problem
Now look at the horse system.
The opposite reaction force by the cart on the horse restrains the
horse.
Without this force, the horse could freely gallop to the market.
The horse moves forward by interacting with the ground.
When the horse pushes backward on the ground, the ground
simultaneously pushes forward on the horse.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 100

Horse-Cart Problem
Look at the horse-cart system as a whole.
The pull of the horse on the cart and the reaction of the cart on the
horse are internal forces within the system.
They contribute nothing to the acceleration of the horse-cart
system. They cancel and can be neglected.
To move across the ground, there must be an interaction
between the horse-cart system and the ground.
It is the outside reaction by the ground that pushes the
system.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 101

Quick Question
What is the net force that acts on the cart?
On the horse?
On the ground?
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Quick Question
What is the net force that acts on the cart? ∑ 𝑭𝑭 = 𝑷𝑷 − 𝒇𝒇
On the horse? ∑ 𝑭𝑭𝑯𝑯 = 𝑷𝑷 − 𝑭𝑭
On the ground? ∑ 𝑭𝑭𝑮𝑮 = 𝒇𝒇 − 𝑭𝑭
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 103

Action-Reaction Pairs
If a sheet of paper is held in midair, the heavyweight
champion of the world could not strike the paper with a
force of 200 N (45 pounds).
The paper is not capable of exerting a reaction force of
200 N, and you cannot have an action force without a
reaction force.
If the paper is against the wall, then the wall will easily
assist the paper in providing 200 N of reaction force, and
more if needed!
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 104

Vectors
Vector components
Vertical and horizontal components of a
vector are perpendicular to each other.
Determined by resolution.
As the stone is released, its vertical
component and its horizontal component
are given as vertical and horizontal
vectors. The velocity of the stone
continues from the release point, going
between the other components. A
dashed line rises and falls below the
velocity component of the stone.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 105

Quick Question
Nellie Newton pulls on the sled as shown.
Which component of her force F is greater?
What two other forces (not shown) act on the sled?
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 106

Quick Question
Nellie Newton pulls on the sled as
shown.
Which component of her force F is
greater?
The horizontal component Fx is
greater.

What two other forces (not shown) act
on the sled?
Weight mg and normal N also act on
the sled.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 107

Summary
So, our study of forces so far amounts to knowing
Newton’s Three Laws:
1. (Law of Inertia) An object will remain in equilibrium
unless the net force on that object is not zero.
2. If the net force is not zero, then it will accelerate
according to Σ𝐹𝐹⃗𝐹𝐹 = 𝑚𝑚𝑎𝑎
⃗.
𝑎𝑎
3. For every (action) force, there is a (reaction) force of
equal magnitude but opposite direction.
 Physics 110 - Lecture 2 - Summer 2024 - Sonia Katdare 108

Summary
To solve any force problem, you can just follow these
steps:
1. Draw a FBD for each system (mass) of interest. Clearly
label all forces as vectors with their directions.
2. Add up the forces (possibly with components in each
⃗𝐹𝐹.
direction) to get Σ𝐹𝐹
3. Use Newton’s 2nd Law Σ𝐹𝐹 ⃗𝐹𝐹 = 𝑚𝑚𝑎𝑎 (or, if in equilibrium,
Newton’s 1st Law with 𝑎𝑎
⃗ = 0).