Lesson 5: Newtons Laws

Question 1

Define and give units for:

Force

Answer 1

Force is the change in velocity per unit time that a given mass is experiencing. Force can also be thought of as the change in momentum per unit time.

The SI unit of force is the Newton (N),
1N = 1 kg*m/s^2

Question 2

Describe Newton’s first law of motion.

Answer 2

aka the Law of Inertia: An object in motion will continue with constant velocity unless acted on by a net force.

Similarly, an object at rest will continue to remain at rest until acted on by a net force.

Question 3

What must be true about the acceleration of an object, if all forces acting on it cancel?

Answer 3

What must be true about the acceleration of an object, if all forces acting on it cancel?

Question 4

What is the relationship between force, mass, and acceleration in Newton’s second law of motion?

Answer 4

Fnet = ma

Note: net force and acceleration are both vectors, and must be pointing in the same direction.

Question 5

What is the proportional change in force to make an object move with twice its original acceleration?

Answer 5

Twice the original force must be applied.

From Newton’s second law, F=ma. Force and acceleration are directly proportional.

Question 6

How does Newton’s third law of motion describe the forces between two objects?

Answer 6

F1on2 = -F2on1

For every force from one object on a second, there is an equal and opposite force from the second back on the first.

Question 7

What is the formula for the universal law of gravitation?

Answer 7

Fg = Gm1m2 / r^2

Where:
G = gravitational constant in N*m^2/kg^2
m1 and m2 = masses in kg
r = distance between masses in m

Question 8

What is the proportional change in gravitational force between two objects, if the distance between them doubles?

Answer 8

Force is decreased to 1/4.

Since F is proportional to 1/r^2, doubling r will reduce the force by a factor of 4.

Question 9

What is the proportional change in gravitational force between two objects, if the distance between them halves and each object’s mass also halves?

Answer 9

No change in force.

Since each mass is directly proportional to F, halving each mass will result in 1/4 the original F. But, since F is proportional to 1/r^2, halving r will result in 4x F. The net change in F is the product both factors: 4(1/4) = 1, no change.

Question 10

What is the more convenient relationship for force on a mass, due to gravity on Earth?

Answer 10

F = mg

Where:
F = force in N
m = mass in kg
g = acceleration due to gravity (9.8 m/s^2)

Question 11

What is the magnitude of the force acting downward on an apple with mass 0.2kg on Earth?

Answer 11

2N.

F = mg = 0.2(9.8) ≈ 2N

Note: if the apple is resting on the ground, it will also be subject to an equivalent normal force pointing upwards.

Question 12

Define:

Weight

Answer 12

Weight is explicitly the force on an object due to gravity. W=mg

Weight if often confused with mass; an object with one weight on Earth will have a different, lesser, weight on the moon, but its mass will remain constant.

Question 13

What will the proportional weight of an object be on the moon, if the moon has 1/6 Earth’s gravity?

Answer 13

The object will have 1/6 the weight it had on Earth.

Since W is proportional to the acceleration due to gravity, the moon’s lesser gravity will produce a proportionally lesser weight.

Question 14

Define:

Normal force

Answer 14

When two objects are touching, there exists an opposing force between the two objects and perpendicular to the surface in contact. This is the normal force.

Often, on the AP exam, normal force is opposing the force due to gravity.

Question 15

What is the normal force for a book of mass 0.5 kg sitting stationary on a table?

Answer 15

5N directed towards the book, from the table.

The force pulling down on the book due to gravity is
F = mg = (0.5)10 = 5N downwards towards the table. Since the book is stationary, we know that normal force is equal and opposite; hence it must also be 5N in magnitude.

Question 16

What is the relationship between normal force and friction for a static object?

Answer 16

Static friction (or rolling friction) is a force that opposes any two surfaces in contact from sliding over each other.

Fs ≤ μsFN

Where:
Fs = force of static friction in N
μs = coefficient of static friction
FN = normal force in N

Question 17

What is the relationship between normal force and friction for a sliding object?

Answer 17

Kinetic friction (or sliding friction) is a force that opposes the motion of two surfaces sliding across one another.

Fk = μkFN

Where:
Fk = force of kinetic friction in N
μk = coefficient of kinetic friction
FN = normal force in N

Question 18

Why is there an equals sign for the force of kinetic friction, but an inequality for the force of static friction?

Answer 18

Kinetic friction only depends on the composition of the two moving surfaces in contact, hence will be one value.

Static friction opposes any amount of force applied while the object remains immobile, hence its value can vary from zero up to the maximum for those surfaces.

Question 19

In which of the following scenarios is static friction between the surfaces higher than kinetic friction?

1) A brick on ice
2) A brick on asphalt
3) An ice block on glass
4) An ice block on rubber

Answer 19

All of them. Static friction is always higher than kinetic friction for any pair of surfaces in contact.

Corollary: it always takes more force to start an object sliding than it does to keep it sliding.

Question 20

What formulas give the component forces for the force due to gravity on an inclined plane?
(note that by convention the “x” axis is along the slope of the plane, and the “y” axis is perpendicular to the plane)

Answer 20

Fx=mg sinθ

Fy=mg cosθ

Since these are opposite from how we normally compute components, a way to remember the x component is: sine is for slope.

Question 21

What calculation will give you the normal force on a box of mass m, on an inclined plane with angle θ?

Answer 21

Since the box is not sinking into the slope, nor launching up off of the slope, the net force acting perpendicular to the slope must be zero. Hence, Fy=-FN

Question 22

What is the force of static friction, if the box does not start to slide down the plane?

Answer 22

There are two forces parallel to the slope of the plane; the component of gravity parallel to the plane, with magnitude mg sin(θ), and the force of static friction, pointing in the opposite direction.

These forces must be equal and opposite to prevent motion.

Question 23

In the pulley system demonstrated below, m2 is twice the mass of m1 and there is no net movement. What is the relationship between the tension in the string at points 1 and 2?

Answer 23

The tensions are equal.

A key to all pulley questions is to remember that the tension in the string running through the system is always constant since it is all one string and we assume the mass of the string is negligible.

Question 24

What is the force F in the pulley apparatus below, with respect to the mass m1, assuming that all masses are stationary and no friction exists?

Answer 24

There are two forces acting on m1; gravity and tension. If the box isn’t moving, they must be equal and opposite, so T = -m1g. Since tension is constant through the string, the force on m2 from tension must also be F = -T = m1g.

Question 25

What is the force F in the pulley apparatus below, with respect to the mass m2, assuming that all masses are stationary and no friction exists?

Answer 25

F = -m2g sinθ

There are two forces acting on the box along the inclined plane: the x component of gravity and the tension in the string. If the box isn’t moving, they must be equal and opposite. Hence
F = T = -m2g sinθ.

Question 26

Give examples of contact forces.

Answer 26

Frictional Force
Normal Force
Force of Tension
Force of Drag
Applied Force
Spring Force

Question 27

Give examples of field forces.

Answer 27

Force of gravity
Electric Force
Magnetic Force

Question 28

Give 2 models to calculate the force of drag.

Answer 28

FD = 1/2Av^2

Where:
A = cross-sectional area in m^2
v = velocity in m/s

FD = 1/4ρACdv^2

Where:
A = cross-sectional area in m^2
ρ = density of fluid object is traveling through in kg/m^3
Cd = drag coefficient which is unitless
v = velocity in m/s

Question 29

Give the equation for terminal velocity.

Answer 29

Where:

VT = terminal velocity in m/s
m = mass of object in kg
g = acceleration due to gravity in m/s^2
C = drag coefficient which is unitless
ρ = density of fluid object is traveling through in kg/m^3
A = cross-sectional area in m^2

Question 30

What is the equation for the spring force?

Answer 30

Hooke’s Law

FS = -kΔx

Where:
FS = Spring Force in N
k = spring constant in N/m^2
Δx = the displacement of the spring from equilibrium in m.