HW 4.1 Force problems-SOLNS.pdf, Study notes of Law

The impact forces are equal in magnitude and opposite in direction (Newton's 3rd Law). The truck hits the bike and the bike hits back with an equal and ...

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Practice Problems, Chapter 4 Name: ___________________________
ļƒ„ļ€½amF 

mgFWeight g
Use separate sheets/ notebook to answer the questions. Show your work clearly
1. Why do you lunge forward when your car suddenly comes to a halt? Because your body wants to
continue to move in a straight line at constant speed. When the car comes to a sudden halt, the upper
part of the body continues forward (as predicted by Newton's first law) if the force exerted by the
lower back muscles is not great enough to give the upper body the same deceleration as the car. The
lower portion of the body is held in place by the force of friction exerted by the car seat and the floor
Why are you pressed backwards against a seat when your car rapidly accelerates? In your
explanations refer to Newton’s Laws. When the car rapidly accelerates, the upper part of the body
tries to remain at a constant velocity (again as predicted by Newton's first law). If the force provided
by the lower back muscles is not great enough to give the upper body the same acceleration as the car,
the upper body appears to be pressed backward against the seat as the car moves forward.
2. The net external force acting on an object is zero. Is it possible for the object to be traveling with a
velocity that is not zero? If your answer is yes, state what conditions must be placed on the magnitude
and direction of the velocity. If your answer is no, provide a reason for your answer.
YES. If the net external force acting on an object is zero, it is possible for the object to be traveling
with a nonzero velocity. According to Newton’s 1st and 2nd laws, if the net external force Fnet is zero,
the acceleration a is also zero. If the acceleration is zero, the velocity must be constant, both in
magnitude and in direction. Thus, an object can move with a constant nonzero velocity when the net
external force is zero.
3. Newton’s second Law indicates that when a net force acts on an object, it must accelerate. Does this
mean that when two or more forces are applied to an object simultaneously, it must accelerate?
Explain. No, if there are multiple forces acting on an object, they could all balance each other out or
all add (vectorally) to zero. If the NET force were zero, then the acceleration would be zero.
4. A 7.00 kg bowling ball experiences a net force of 5.00 N. What will be its
acceleration? Acceleration would be in same direction as the force
5. An astronaut applies a force of 500 N to an asteroid and it accelerates at 7.00 m/s2. What is the
asteroid’s mass?
6. Acceleration due to gravity on the moon’s surface is 1/6th that on Earth. An astronaut’s life support
backpack weighs 300. lb on Earth. In pounds, what does it weigh on the moon? Because weight =
mg, it is proportional to the acceleration due to gravity. On the moon, where g is 1/6th that of Earth, a
person weighing 300lb on Earth would weight 1/6th of that on the moon – 50lb)
2
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F
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500 
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Partial preview of the text

Download HW 4.1 Force problems-SOLNS.pdf and more Study notes Law in PDF only on Docsity!

Practice Problems, Chapter 4 Name: ___________________________

 F^ ^ ma

Weight  Fg  mg

Use separate sheets/ notebook to answer the questions. Show your work clearly

  1. Why do you lunge forward when your car suddenly comes to a halt? Because your body wants to

continue to move in a straight line at constant speed. When the car comes to a sudden halt, the upper

part of the body continues forward (as predicted by Newton's first law) if the force exerted by the

lower back muscles is not great enough to give the upper body the same deceleration as the car. The lower portion of the body is held in place by the force of friction exerted by the car seat and the floor

Why are you pressed backwards against a seat when your car rapidly accelerates? In your

explanations refer to Newton’s Laws. When the car rapidly accelerates, the upper part of the body

tries to remain at a constant velocity (again as predicted by Newton's first law). If the force provided

by the lower back muscles is not great enough to give the upper body the same acceleration as the car,

the upper body appears to be pressed backward against the seat as the car moves forward.

  1. The net external force acting on an object is zero. Is it possible for the object to be traveling with a

velocity that is not zero? If your answer is yes, state what conditions must be placed on the magnitude and direction of the velocity. If your answer is no, provide a reason for your answer.

YES. If the net external force acting on an object is zero, it is possible for the object to be traveling

with a nonzero velocity. According to Newton’s 1 st^ and 2nd^ laws, if the net external force Fnet is zero,

the acceleration a is also zero. If the acceleration is zero, the velocity must be constant, both in

magnitude and in direction. Thus, an object can move with a constant nonzero velocity when the net

external force is zero.

  1. Newton’s second Law indicates that when a net force acts on an object, it must accelerate. Does this

mean that when two or more forces are applied to an object simultaneously, it must accelerate?

Explain. No, if there are multiple forces acting on an object, they could all balance each other out or

all add (vectorally) to zero. If the NET force were zero, then the acceleration would be zero.

  1. A 7.00 kg bowling ball experiences a net force of 5.00 N. What will be its

acceleration? Acceleration would be in same direction as the force

  1. An astronaut applies a force of 500 N to an asteroid and it accelerates at 7.00 m/s 2 . What is the asteroid’s mass?
  2. Acceleration due to gravity on the moon’s surface is 1/6th that on Earth. An astronaut’s life support

backpack weighs 300. lb on Earth. In pounds, what does it weigh on the moon? Because weight =

mg, it is proportional to the acceleration due to gravity. On the moon, where g is 1/ th that of Earth, a

person weighing 300lb on Earth would weight 1/ th of that on the moon – 50lb)

2

  1. 71 / 7

m s m

F

a

F ma





kg a

F

m

F ma





10 N 10 N

10 N 5 N

10 N 10 N

7 N

3 N

60 o

13 N

7.5 N

40kg

F 2 =40N

F 1 =25N

Fnet

q

  1. Determine the net force (magnitude and direction) acting on the objects below. Each object has a

mass of 5 kg. Determine the acceleration (magnitude and direction) if there is one.

Net Force: ______0_________

Acceleration: ____0_________

Net Force: ____5N, left _______

Acceleration: __1 m/s^2 , left ______

Net Force: ___4 N up ______

Acceleration: __4/5 m/s 2 up ___

Net Force: ____15N right ______

Acceleration: ___3 m/s 2 right _

  1. Two ropes are attached to a 40.0 kg object. The first rope applies a force of 25.0 N and the second a

force of 40.0 N. If the two ropes are perpendicular to each other, what is the resultant acceleration of

the object? (Hint: Draw a force diagram showing the forces acting on the object. Find the net force

by adding the two forces by components. Use the net force to find the magnitude and direction of the

acceleration. Remember that the direction of the acceleration is in the same direction as the net force.)

Magnitude Direction

2

2 2

2 1

1 2

m s m

F

a

F ma

F F F N
F F F

net

net





o

F

F
F
F

tan 58

tan

1

(^12)

1

2



q

q

  1. When you jump up, does the world recoil downward? Explain. When you jump up, you push on the

world causing it to recoil in response to the push. However the mass/inertia of the Earth is so large,

that the acceleration of the Earth in response to the push is tiny (a=Fnet/m). The tiny acceleration

causes the Earth to recoil by an amount that is much

  1. a) When a rifle is fired, how does the size of the force of the rifle on the bullet

compare to the force of the bullet on the rifle? The forces are equal in

magnitude and opposite in direction. The gun pushes the bullet and the bullet pushes back on the gun with an equal and opposite force.

b) How do the accelerations of the rifle and bullet compare? Why? The forces are equal but the mass of the rifle and bullet are NOT equal so the accelerations will not be equal. The bullet has more acceleration because it has smaller mass Frifle = Fbullet

Mrar=mbAb

  1. a) If a bicycle and a massive truck have a head-on collision, upon which vehicle is the impact force

greater? The impact forces are equal in magnitude and opposite in

direction (Newton’s 3 rd Law). The truck hits the bike and the

bike hits back with an equal and opposite force.

b) Which vehicle undergoes the greater acceleration or change

in velocity? Why? The bike undergoes the greater acceleration because it has smaller mass. The

impact forces are equal but the mass of the bike and truck are NOT equal so the accelerations will

not be equal.

  1. Suppose two carts, one twice as massive as the other, fly apart when

the compressed spring that joins them is released. How fast does the

heavier cart roll compared to the lighter cart? Explain.

When they fly apart, they push on each other with equal and opposite forces. Therefore the car with twice the mass will have

half the acceleration of the other car. Because they start from rest, the 2m car with half the

acceleration will have half the speed of the m car.

  1. A semi-truck collides with a car with a force of 5000N. The semi-truck has a mass of 2000kg and the

car has a mass of 500kg. a) What force did the car exert on the semi-truck at impact? Since the truck exerted a force of 5000N on the car, the car exerted an equal and opposite force on the truck.

b) What was the acceleration of the truck when it hit the car? On impact, the only horizontal force acting on the truck is the impact force on the truck by the car (FTC). See the figure at right. That is the net force

FTC

FCT

2

  1. 5 / 2000

m s m

F

aT

F ma

F ma

T

TC

TC T T

c) How much did the car accelerate when it was hit? On impact, the only horizontal force acting on

the car is the impact force on the car by the truck (FCT). See the figure at right. That is the net force

d) If the action statement is ā€˜The semi-truck exerts a force on the car,’ what is the reaction statement?

The car exerts an equal and opposite for on the truck.

2 10 / 500

m s m

F

a

F ma

F ma

C

CT C

CT C C

 