Newtons’s Laws Chapters 4&5. Chapter 4: Forces and Newton’s Laws of Motion Section 1: Concepts...

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Newtons’s Laws

Chapters 4&5

Chapter 4:Forces and Newton’s Laws of Motion

Section 1:

Concepts of Force and Mass

Introducing Forces

A force is a push or pull on an object. Forces are what cause an object to accelerate, or to

change its velocity by speeding up, slowing down, or changing direction.

It is important that we learn to identify all the forces acting on an object, and to draw these forces as vectors.

Contact forces arise from physical contact.

Drawing Forces

What are the forces acting on a book as it rests on the table?

Textbook

Gravity pulls downon the book

FTTable pushes upon the book

Two Methods of Drawing Forces

Force Diagram Free Body Diagram

Textbook

Sample problem:

Draw a force diagram and a free body diagram for a monkey hanging motionless by two arm from two vines attached to neighboring trees.

Mass is a measure of the amount of “stuff” contained in an object.

It is the measure of how much inertia an object has.

Scalar value Measured in kg

Section 2:

Newton’s First Law of Motion

1st Law Of Motion - Inertia

An object remains in constant motion unless acted upon by and unbalanced force

It is often said that the Law of Inertia violates “common sense”. Why do you think some people say that?

If there is zero net force on a body, it cannot accelerate, and therefore must move at constant velocity. This means: the body cannot turn. the body cannot speed up. The body cannot slow down.

Mass and Inertia

Chemists like to define mass as the amount of “stuff” or “matter” a substance has.

Physicists define mass as inertia, which is the ability of a body to resist acceleration by a net force.

What is the relationship between mass and inertia? Inertia is the natural tendency of an object to remain

at rest in motion at a constant speed along a straight line.

The mass of an object is a quantitative measure of inertia.

Measured in kilograms (kg)

Net Force

The net force on an object is the vector sum of all forces acting on that object.

The SI unit of force is the Newton (N).

Individual Forces Net Force

10 N4 N 6 N

Net Forces

Individual Forces Net Force

Question #1

When you sit on a chair, the resultant force on you is

A) zero.

B) up.

C) down.

D) depends on your weight.

E) depends on the angle of the chair

Question #2If an object is moving can you conclude there are forces acting

on it? If an object is at rest, can you conclude there are no forces acting on it? Consider each of the following situations. In which one of the following cases, if any, are there no forces acting on the object?

a) A bolt that came loose from a satellite orbits the earth at a constant speed.

b) After a gust of wind has blown through a tree, an apple falls to the ground.

c) A man rests by leaning against a tall building in downtown Dallas.

d) Sometime after her parachute opened, the sky diver fell toward the ground at a constant velocity.

e) All of the above

Question #3

A child is driving a bumper car at an amusement park. During one interval of the ride, she is traveling at the car’s maximum speed when she crashes into a bumper attached to one of the side walls. During the collision, her glasses fly forward from her face. Which of the following statements best describes why the glasses flew from her face?

a) The glasses continued moving forward because there was too little force acting on them to hold them on her face during the collision.

b) During the collision, the girl’s face pushed the glasses forward.

c) The glasses continued moving forward because the force of the air on them was less than the force of the girl’s face on them.

d) During the collision, the car pushed the girl forward causing her glasses to fly off her face.

e) During the collision, the wall pushed the car backward and the girl reacted by pushing her glasses forward.

Frame of Reference

An inertial reference frame is one in which Newton’s law of inertia is valid.

All accelerating reference frames are non-inertial. We assume earth is an inertial reference frame

since the acceleration is small.

Question #4

If an object is moving can you conclude there are forces acting on it? If an object is at rest, can you conclude there are no forces acting on it? Consider each of the following situations. In which one of the following cases, if any, are there no forces acting on the object?

a) A bolt that came loose from a satellite orbits the earth at a constant speed.

b) After a gust of wind has blown through a tree, an apple falls to the ground.

c) A man rests by leaning against a tall building in downtown Dallas.

d) Sometime after her parachute opened, the sky diver fell toward the ground at a constant velocity.

e) Forces are acting on all of the objects in choices a, b, c, and d.

Question #5

A child is driving a bumper car at an amusement park. During one interval of the ride, she is traveling at the car’s maximum speed when she crashes into a bumper attached to one of the side walls. During the collision, her glasses fly forward from her face. Which of the following statements best describes why the glasses flew from her face?

a) The glasses continued moving forward because there was too little force acting on them to hold them on her face during the collision.

b) During the collision, the girl’s face pushed the glasses forward.

c) The glasses continued moving forward because the force of the air on them was less than the force of the girl’s face on them.

d) During the collision, the car pushed the girl forward causing her glasses to fly off her face.

e) During the collision, the wall pushed the car backward and the girl reacted by pushing her glasses forward.

Section 3:

Newton’s Second Law of Motion

Newton’s 2nd Law

Quantifies the magnitude and direction of the accelerations. When a net force is present, the acceleration of the object is

proportional to the net force and inversely proportional to the mass of the object.

The direction of the acceleration is the same as the direction of the net force.

ac is the constant added that “fixes” the units. usually ignored/forgotten

maFF net

SI Unit of Force

SI Unit for Force

This combination of units is called a newton (N).

Working 2nd Law Problems

1. Identify the system being accelerated.

2. Define a coordinate system.

3. Identify forces by drawing a force or free body diagram.

4. Explicitly write F=ma

5. Replace F with the actual forces in your free body diagram.

6. Substitute numeric values, where appropriate, and solve for unknowns.

Question #6

A car of mass m is moving at a speed 3v in the left lane on a highway. In the right lane, a truck of mass 3m is moving at a speed v. As the car is passing the truck, the driver notices that the traffic light ahead has turned yellow. Both drivers apply the brakes to stop ahead. What is the ratio of the force required to stop the truck to that required to stop the car? Assume each vehicle stops with a constant deceleration and stops in the same distance x.

a) 1/9 b) 1/3

c) 1 d) 3

Question #7

The graph shows the velocities of two objects as a function of time. During the intervals A, B, and C indicated, net forces , , and act on the two objects, respectively. If the objects have equal mass, which one of the following choices is the correct relationship between the magnitudes of the three net forces?

a) FA > FB = FC

b) FC > FA > FB

c) FA < FB < FC

d) FA = FB = FC

e) FA = FC > FB

AF��

BF��

CF��

Comparison of units

So, what’s all this mean?

A man stands on a scaleinside a stationary elevator.

Forces acting on the man

Reading on scale

And then…

When Moving Upward With Constant Velocity

0m mgN

Reading on scale

And then…

When Moving Upward With Constant Acceleration

am mgN

Reading on scale

And then…

When Moving Downward With Constant Acceleration

am Nmg

Reading on scale

Section 4:

The Vector Nature of Newton's Second Law of Motion

Section 4-The short, short version

Forces are a vector Just as with velocity, acceleration, Forces that are

perpendicular are independent of each other

xx maFyy maF

is equivalent to

Question #8

In a grocery store, you push a 14.5-kg cart with a horizontal force of 12.0 N. If the cart starts at rest, how far does it move in 3.00 seconds?

Question #9

A catcher stops a 92 mph pitch in his glove, bringing it to rest in 0.15 m. If the force exerted by the catcher is 803 N, what is the mass of the ball?

Section 5:

Newton’s 3rd Law of Motion

Newton’s Third Law

For every action there exists an equal and opposite reaction.

If A exerts a force F on B, then B exerts a force of -F on A.

Example Problem:

You rest a book on a table.

a) Identify the forces acting on the book with a free body diagram.

b) Are these forces equal and opposite?

c) Are these forces an action-reaction pair? Why or why not?

Requirements for Newton’s Laws

The 1st and 2nd laws require that ONE system be analyzed and that ALL the forces on the system be accounted for.

The 3rd law requires that TWO systems be analyzed and that the forces of interaction between the two be accounted for.

Question #10

A water skier is being pulled by a rope attached to a speed boat moving at a constant velocity. Consider the following four forces: (1) the force of the boat pulling the rope, (2) the force of the skier pulling on the rope, (3) the force of the boat pushing the water, and (4) the force of the water pushing on the boat. Which two forces are an “action-reaction” pair that is consistent with Newton’s third law of motion?

a) 1 and 2 b) 2 and 3

c) 2 and 4 d) 3 and 4

e) 1 and 4

Question #11

A large crate is lifted vertically at constant speed by a rope attached to a helicopter. Consider the following four forces that arise in this situation: (1) the weight of the helicopter, (2) the weight of the crate, (3) the force of the crate pulling on the earth, and (4) the force of the helicopter pulling on the rope. Which one of the following relationships concerning the forces or their magnitudes is correct?

a) The magnitude of force 4 is greater than that of force 2.

b) The magnitude of force 4 is greater than that of force 1.

c) Forces 3 and 4 are equal in magnitude, but oppositely directed.

d) Forces 2 and 4 are equal in magnitude, but oppositely directed.

e) The magnitude of force 1 is less than that of force 2.

Question #12An astronaut is on a spacewalk outside her ship in “gravity-free” space. Initially, the spacecraft and astronaut are at rest with respect to each other. Then, the astronaut pushes to the left on the spacecraft and the astronaut accelerates to the right. Which one of the following statements concerning this situation is true?

a) The astronaut stops moving after she stops pushing on the spacecraft.

b) The velocity of the astronaut increases while she is pushing on the spacecraft.

c) The force exerted on the astronaut is larger than the force exerted on the spacecraft.

d) The spacecraft does not move, but the astronaut moves to the right with a constant speed.

e) The force exerted on the spacecraft is larger than the force exerted on the astronaut.

Section 6:

Types of Forces: An Overview

Two Types of Forces

Fundamental Forces

Always present in nature

Gravitational, Strong Nuclear, Electroweak

Non-fundamental Forces

Present in certain situations usually as a result of

Fundamental and applied forces.

Normal, Tension, Friction

Natural Forces

Types Range

Gravitational Unlimited

Electromagnetic Unlimited

Weak Nuclear 1012 m

Strong Nuclear 1015 m

Section 7:

The Gravitational Force

Newton’s Law of Universal Gravitation

Every particle in the universe exerts an attractive force on every other particle.

A particle is a piece of matter, small enough in size to be regarded as a mathematical point.

The force that each exerts on the other is directed along the line joining the particles.

For two particles that have masses m1 and m2 and are separated by a distance r, the force has a magnitude given by:

mmGF 2211 kgmN10673.6 G

Weight

The weight of an object on or above the earth is the gravitational force that the earth exerts on the object.

The weight always acts downwards, toward the center of the earth.

On or above another astronomical body, the weight is the gravitational force exerted on the object by that body.

SI Unit of Weight: newton (N)

Relation Between Mass and Weight

mMGW E

On the earth’s surface

242211

sm 80.9

m 106.38

kg 1098.5kgmN1067.6

Question #13

A cannon fires a ball vertically upward from the Earth’s surface. Which one of the following statements concerning the net force acting on the ball at the top of its trajectory is correct?

a) The net force on the ball is instantaneously equal to zero

newtons at the top of the flight path.

b) The direction of the net force on the ball changes from upward

to downward.

c) The net force on the ball is less than the weight, but greater

than zero newtons.

d) The net force on the ball is greater than the weight of the ball.

e) The net force on the ball is equal to the weight of the ball.

Question #14

If an object at the surface of the Earth has a weight W, what would be the weight of the object if it was transported to the surface of a planet that is one-sixth the mass of Earth and has a radius one third that of Earth?

a) 3W b) 4W/3

c) W d) 3W/2

e) W/3

Question #15

Two objects that may be considered point masses are initially separated by a distance d. The separation distance is then decreased to d/3. How does the gravitational force between these two objects change as a result of the decrease?

a) The force will not change since it is only dependent on the

masses of the objects.

b) The force will be nine times larger than the initial value.

c) The force will be three times larger than the initial value.

d) The force will be one third of the initial value.

e) The force will be one ninth of the initial value.

Section 8:

The Normal Force

Definition of the Normal Force

The normal force is one component of the force that a surface exerts on an object with which it is in contact – namely, the component that is perpendicular to the surface.

Sample Problem

If you apply an 11 N force to a 15 N block which is resting on a table, what is the normal force the table exerts on the block?

N 26NF

0N 11N 15 NF

AWN FFFF

What is the normal force if instead of pushing down on the 15 N block, you lift it with 11 N of force?

Sample Problem

0N 11N 15 NF

AWN FFFF

Apparent Weight

What we feel as “our weight” is the normal force acting on us.

mamgFF Ny

mamgFN

apparent weight

trueweight

Apparent Weight

Question #16

A free-body diagram is shown for the following situation: a force pulls on a crate of mass m on a rough surface. The diagram shows the magnitudes and directions of the forces that act on the crate in this situation. represents the normal force on the crate, represents the acceleration due to gravity, and represents the frictional force. Which one of the following expressions is equal to the magnitude of the normal force?

a) P f / b) P f

c) P f mg d) mg

e) zero

P��

NF��

Question #17

4.8.3. Consider the three cases shown in the drawing in which the same force is applied to a box of mass M. In which case(s) will the magnitude of the normal force on the box equal (F sin + Mg)?

a) Case One only

b) Case Two only

c) Case Three only

d) Cases One and Two only

e) Cases Two and Three only

F��

Question #18Consider the situation shown in the drawing. Block A has a mass 1.0 kg and block B has a mass 3.0 kg. The two blocks are connected by a very light rope of negligible mass that passes over a pulley as shown. The coefficient of kinetic friction for the blocks on the ramp is 0.33. The ramp is angled at = 45. At time t = 0 s, block A is released with an initial speed of 6.0 m/s. What is the tension in the rope?

a) 11.8 N

b) 7.88 N

c) 15.8 N

d) 13.6 N

e) 9.80 N

Section 9:

Static and Kinetic Friction Forces

Static and Kinetic Frictional Forces

When an object is in contact with a surface there is a force acting on that object. The component of this force that is parallel to the surface is called the frictional force.

Static Friction

When the two surfaces

are not sliding across one

another the friction is

called static friction.

Static Friction

The magnitude of the static frictional force can have any value from zero up to a maximum value.

MAXss ff

10 s is called the coefficient of static friction.

Static Friction

Note that the magnitude of the frictional force does not depend on the contact area of the surfaces.

Static vs. Kinetic Friction

Static friction opposes the impending relative motion between two objects.

Kinetic friction opposes the relative sliding motion motions that actually does occur.

Nkk Ff

10 s is called the coefficient of kinetic friction.

Sample Problem

If a 40 pound child is sledding on a level surface, what is the frictional force if the coefficient of friction is 0.05?

Nkk Ff

2sm80.9kg4005.0

Question #19

On a rainy evening, a truck is driving along a straight, level road at 25 m/s. The driver panics when a deer runs onto the road and locks the wheels while braking. If the coefficient of friction for the wheel/road interface is 0.68, how far does the truck slide before it stops?

a) 55 m b) 47 m

c) 41 m d) 36 m

e) 32 m

Question #20Three pine blocks, each with identical mass, are sitting on a rough surface as shown. If the same horizontal force is applied to each block, which one of the following statements is false?

a) The coefficient of kinetic friction is the same for all three blocks.

b) The magnitude of the force of kinetic friction is greater for block 3.

c) The normal force exerted by the surface is the same for all three blocks.

d) Block 3 has the greatest apparent area in contact with the surface.

e) If the horizontal force is the minimum to start block 1 moving, then that same force could be used to start block 2 or block 3 moving.

Question #21

A 1.0-kg block is placed against a wall and is held stationary by a force of 8.0 N applied at a 45° angle as shown in the drawing. What is the magnitude of the friction force?

a) 3.7 N

b) 4.1 N

c) 5.8 N

d) 7.0 N

e) 8.0 N

Section 10:

The Tension Force

Cables and ropes transmit forces through tension.

A massless rope will transmit tension undiminished from one end to the other.

If the rope passes around a massless, frictionless pulley, the tension will be transmitted to the other end of the rope undiminished.

Question #22

Some children are pulling on a rope that is raising a bucket via a pulley up to their tree house. The bucket containing their lunch is rising at a constant velocity. Ignoring the mass of the rope, but not ignoring air resistance, which one of the following statements concerning the tension in the rope is true?

a) The magnitude of the tension is zero newtons.

b) The direction of the tension is downward.

c) The magnitude of the tension is equal to that of the weight of the bucket.

d) The magnitude of the tension is less than that of the weight of the bucket.

e) The magnitude of the tension is greater than that of the weight of the bucket.

Question #23

One end of a string is tied to a tree branch at a height h above the ground. The other end of the string, which has a length L = h, is tied to a rock. The rock is then dropped from the branch. Which one of the following statements concerning the tension in the string is true as the rock falls?

a) The tension is independent of the magnitude of the rock’s acceleration.

b) The magnitude of the tension is equal to the weight of the rock.

c) The magnitude of the tension is less than the weight of the rock.

d) The magnitude of the tension is greater than the weight of the rock.

e) The tension increases as the speed of the rock increases as it falls.

Question #24

A rock is suspended from a string. Barbara accelerates the rock upward with a constant acceleration by pulling on the other end of the string. Which one of the following statements concerning the tension in the string is true?

a) The tension is independent of the magnitude of the rock’s

acceleration.

b) The magnitude of the tension is equal to the weight of the rock.

c) The magnitude of the tension is less than the weight of the rock.

d) The magnitude of the tension is greater than the weight of the rock.

e) The tension decreases as the speed of the rock increases as it

rises.

Section 11:

Equilibrium Applications of Newton’s Laws of Motion

Definition of Equilibrium

An object is in equilibrium when it has zero acceleration.

Reasoning Strategy

Select an object(s) to which the equations of equilibrium are to be applied.

Draw a free-body diagram for each object chosen above.

Include only forces acting on the object, not forces the object exerts on its environment.

Choose a set of x, y axes for each object and resolve all forces in the free-body diagram into components that point along these axes.

Apply the equations and solve for the unknown quantities.

Sample Problem

The picture below shows a traction device used with a foot injury. The weight of the 2.2-kg object creates a tension in the rope that passes around the pulleys. The foot pulley is kept in equilibrium because the foot also applies a force to it. Ignoring the weight of the foot, find the magnitude of the force F .

Solution:

21 35sin35sin0

35cos2

35cos35cos0

35cos80.92.22 2smkgF

Question #25

Consider the following: (i) the book is at rest, (ii) the book is moving at a constant velocity, (iii) the book is moving with a constant acceleration. Under which of these conditions is the book in equilibrium?

a) (i) only b) (ii) only

c) (iii) only d) (i) and (ii) only

e) (ii) and (iii) only

Question #26

A block of mass M is hung by ropes as shown. The system is in equilibrium. The point O represents the knot, the junction of the three ropes. Which of the following statements is true concerning the magnitudes of the three forces in equilibrium?

a) F1 + F2 = F3

b) F1 = F2 = 0.5×F3

c) F1 = F2 = F3

d) F1 > F3

e) F2 < F3

Question #27

A team of dogs pulls a sled of mass 2m with a force . A second sled of mass m is attached by a rope and pulled behind the first sled. The tension in the rope is . Assuming frictional forces are too small to consider, determine the ratio of the magnitudes of the forces and , that is, P/T.

d) 0.5

e) 0.33

P��

T��

P��

T��

Section 12:

Non-equilibrium Applications of Newton’s Laws of Motion

Nonequilibrium Application of Newton’s Laws of Motion When an object is accelerating, it is not in

equilibrium.

xx maF

yy maF

Example 14 Towing a Supertanker

A supertanker of mass m = 1.50 × 108 kg is being towed by two tugboats. The tensions in the towing cables apply forces at equal angles of 30.0° with respect to the tanker's axis. In addition, the tanker's engines produce a forward drive force, whose magnitude is D = 75.0 × 103 N. Moreover, the water applies an opposing force, whose magnitude is R = 40.0 × 103 N. The tanker moves forward with an acceleration that points along the tanker's axis and has a magnitude of 2.00 × 10-3 m/s2. Find the magnitudes of the tensions.

The acceleration is along the x axis so 0ya

Force x component y component

0.30cos1T

0.30cos2T

0.30sin1T

0.30sin2T

0.30cos0.30cos 21

00.30sin0.30sin 21 TTFy

TTT 21

N 1053.10.30cos2

DRmaT x

Question #28

F vo = 0

t = 5 s v = ?

maF tv

kg 5s 5N 20

F = 20 N

m = 5 kg

m/s 20

A constant force F acts on a block of mass m. which is initially at rest. Find the velocity of the block after time t.

Question #29

A force of magnitude F pushes a block of mass 2m, which in turn pushes a block of mass m as shown. The blocks are accelerated across a horizontal, frictionless surface. What is the magnitude of the force that the smaller block exerts on the larger block?

a) F/3

b) F/2

Newtons’s Laws Chapters 4&5. Chapter 4: Forces and Newton’s Laws of Motion Section 1: Concepts...

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