Topic 6: Circular motion and gravitation

Question 1

Circular motion

Answer 1

direction of motion is constantly changing, therefore velocity is constantly changing. Acceleration is the rate of change of velocity

Question 2

(circular motion) speed formula - v

Answer 2

v = (2πr)/T

Question 3

circular acceleration formulas

Answer 3

a = v²/r

a = (4π²r)/T²

Question 4

centripetal force formulas

Answer 4

F=ma

F=(mv²)/r

F=m(ωr)²/r → F=mω²r

Question 5

angular velocity

Answer 5

the angular displacement divided by the time taken

Question 6

linear velocity

Answer 6

v=ωr

Question 7

centripetal acceleration

Answer 7

acceleration is towards the centre of the circle, caused by centripetal force in the same direction. e.g gravity on a satellite

Question 8

How far will an object travel in one revolution?

Answer 8

the object will travel through 2π rads in a time T

Question 9

In what way does the centripetal force act?

Answer 9

It always acts at 90 degrees to the motion of the object undergoing circular motion. Therefore it does not do any work - no displacement of the object in the direction of the force.

Question 10

What happens to a car if the corners are banked?

Answer 10

if a bend is banked, a car travels much faster than on a flat road as friction is not required to produce the centripetal force - instead, it comes from the horizontal component of the reaction force.

Question 11

How can you resolve the reaction force?

Answer 11

It can be resolved into horizontal and vertical components

Question 12

How is vertical circular motion different to horizontal circular motion?

Answer 12

It is different to horizontal in that the force acting on the object varies throughout the motion and the speed of the object may not be constant as energy changes between Ek and Ep

Question 13

What are the forces at the top of a loop?

Answer 13

The two forces acting on a car are the weight force (Fg) and the reaction force of the track pushing down on the car (Fr) and Fc = Fg

Question 14

What is the total unbalanced force in a vertical loop?

Answer 14

Fg+Fr in the downwards direction - provides the centripetal force for the circular motion

Question 15

The faster the car is travelling…

Answer 15

the larger the centripetal force (Fc is proportional to v squared).

The weight force is constant, so it is a reaction force that changes in size as the speed of the car changes (higher the speed, greater reaction force)

Question 16

At the minimum speed needed to move in a vertical circle…

Answer 16

the reaction force at the top of the loop = 0

Question 17

How do you calculate the minimum speed in a vertical circle?

Answer 17

Fc = Fg so (mv²)/r = mg

v²/r = g

v_min = √rg

Question 18

We feel weightless at the top of a loop because…

Answer 18

the weight we feel actually depends on the size of the reaction force, not the size of the weight force - when reaction force is increased or decreased we feel lighter and heavier respectively. Top of loop, reaction force = 0

Question 19

Why do we feel heavier at the bottom of the loop?

Answer 19

Fc is directly upwards towards the centre of the loop.

Using Fc=Fr-Fg, we see that as Fr > mg, therefore we feel heavier

Question 20

We feel heavier in a loop when…

Answer 20

speed increases and/or reaction force decreases

Question 21

Newton’s universal law of gravitation

Answer 21

every single point mass attracts every other point mass with a force that is directly proportional to the product of their masses and inversely proportional to the square of their separation.

Question 22

What is a point mass?

Answer 22

A mass which does not take up any space (infinitely small).

Question 23

Gravitational force formula

Answer 23

F=G(Mm/r²) - both masses will experience the same size force e.g you pull the earth towards you with the same force that it pulls you towards it. The force depends on the masses involved though, and the distance between each other

Question 24

What is a gravitational field?

Answer 24

A region of space where a mass experiences a force because of its mass (a gravitational force).

Question 25

What happens to the field lines when there is a stronger field?

Answer 25

The field lines are closer

Question 26

What is gravitational field strength?

Answer 26

The force, per unit mass, experienced by a small point mass placed in the field.

Question 27

What is a test mass?

Answer 27

A mass that has such a small mass that it does not change the gravitational field in which it is placed

Question 28

If a test mass of mass m experiences force F then…

Answer 28

g=F/m

Question 29

What is g (measured in Nkg^-1)

Answer 29

field strength; a vector quantity (has direction as well as size) and will be the same as the acceleration due to gravity at that point (ms^-2 = Nkg^-1) therefore a=F/m

Question 30

What is the centripetal force for any orbiting object?

Answer 30

Centripetal force = gravitational force

Question 31

What does the speed required to maintain an orbit depend on?

Answer 31

It depends on the radius of the orbit but not the mass of the satellite.

Question 32

What is the acceleration of a satellite?

Answer 32

a = F/m or a=v²/r

Question 33

What are geostationary orbits?

Answer 33

Orbits around the earth such that they stay in the same point above the earth’s surface. To do this the satellite must orbit above the equator with an orbital period equal to the time it takes the earth to rotate once.

Question 34

What is the time Earth takes to rotate once in seconds?

Answer 34

24(hours)x60(minutes)x60(seconds) = 86400s

Question 35

How do you derive Kepler’s Third law?

Answer 35

r³ = GMT²/4π² where G, M, 4 and π² are all constants so r³ is proportional to T² and r³/T² = constant (for any planet this ratio will be constant).

Question 36

What is work done?

Answer 36

Force x distance moved in the direction of the force, and also a transfer of energy

Question 37

What is the period (T)?

Answer 37

The time taken for an object to travel once around the circle (one revolution) (s)

Question 38

What is frequency?

Answer 38

The number of times an object travels around the circle per second (Hz)

Question 39

What is angular displacement?

Answer 39

The angle moved around the circle by an object from where its circular motion starts

Question 40

Is angular displacement a vector or scalar?

Answer 40

Scalar (not considered a vector like linear displacement is)

Question 41

What is a radian?

Answer 41

The angle for which the arc length is equal to the radius

Question 42

How do you go from degrees to radians?

Answer 42

((Angle in degrees) x 2π)/360

Question 43

How do you go from radians to degrees?

Answer 43

((Angle in radians) x 360)/2π

Question 44

For what angles can sin x and x be approximated?

Answer 44

For angles of 10° and under or π/9 rads and lower

Question 45

Why is an object in simple circular motion always accelerating?

Answer 45

Velocity is constantly changing, therefore it is accelerating. This means that there must be an unbalanced force.

Question 46

What is the direction of angular velocity?

Answer 46

Through the the centre of the circular movement in the direction that the motion would be clockwise around it.

Question 47

What are the units of angular speed?

Answer 47

Radians per second (rad s^-1)

Question 48

How is frequency linked to angular speed?

Answer 48

As angular speed is 2π/T. Frequency is 1/T. Therefore angular speed is 2πf too

Question 49

Derive linear velocity with respect to angular velocity

Answer 49

V = d/t so 2πr/T. As angular velocity = 2π/T we can substitue this into the linear velocity so V = ωr

Question 50

Which law explains the existence of centripetal acceleration.

Answer 50

Newton’s first law. Changing velocity indicates an external force to cause this acceleration.

Question 51

In which direction does the centripetal acceleration act in?

Answer 51

It is always in the direction towards the centre of the circle.

Question 52

If turning on a horizontal road, what condition must be met in order for the car not to skid?

Answer 52

The centripetal force requires has to be less that the frictional force:

mv²/r smg

Question 53

When should you use the static or dynamic coefficients of friction for a car turning?

Answer 53

You should use the static when turning, as the frictional force has not been exceeded, if not skidding.

Once skidding, the dynamic coefficient should be used as the frictional force was exceeded and not is dynamic. The sign should also switch to an = sign.

Question 54

How can you find the maximum speed of car turning on a flat road?

Answer 54

mv²/r = μ_dmg

v²/r = μ_dg

v² = μ_drg

v_max = +√μ_drg

Question 55

What is the horizontal component of the normal force (banked corners)?

Answer 55

N sinθ

Question 56

What is the centripetal force for banked corners, in terms of weight?

Answer 56

F_c = N sinθ

as mg = N cosθ (= the vertical component)

N = mg/cosθ

F_c = (mg/cosθ) sinθ

F_c = mg tanθ

Question 57

How do you equate the general centripetal force formula and the banked corner formula?

Answer 57

as F_c = mg tanθ and F_c = mv²/r

mg tanθ = mv²/r

tanθ = v²/rg

Question 58

Examples of banked corners in use

Answer 58

• cyclist tracks (velodromes)
• aeroplanes turning
• high speed trains turning

Question 59

At which point in the verticle circle is the tension most likely to break and why?

Answer 59

At the bottom point as the string tension must overcome weight whilst providing the required centripetal force, therefore it is most likely to be strained and break here.

Question 60

What is the equation for the maximum tension a string can withstand in a verticle circle system?

Answer 60

For it to stay intact:

T_max > mv²/r + mg

Question 61

What is the equation for the maximum linear speed at the bottom of a verticle circle?

Answer 61

√(r/m)(T_max-mg)

[derived from rearranging the maximum tension equation]

Question 62

At what speed does a car going over the bridge lose contact with the road?

Answer 62

At a speed greater or equal to √gr

[derived from equation with car at the top of the bridge]

Question 63

What is the centripetal force of a car on the top of a bridge?

Answer 63

It is entirely the weight

F_c = mg = mv²/r

Question 64

How is energy conserved for a car driving over a bridge?

Answer 64

Kinetic energy at the top + change in gravitational potential energy = kinetic energy at the bottom

(1/2)mv_top² + mg(2r) = (1/2)mv_bottom²

with this you can find that:

T_bottom = T_top + 6mg

Question 65

What can the gravitational field strength also represent?

Answer 65

The acceleration that a mass would experience from being pulled towards another mass