Gravitational Fields

Question 1

How are these two gravitational fields similar? How are they different?

Answer 1

Both are uniform (constant field strength)

Closer field lines represent stronger field

Question 2

How are radial and uniform fields different?

Answer 2

Radial fields have a decreasing field strength

(Field lines increasing in separation)

Uniform fields have a constant field strength

(Field lines constant\ separation)

Question 3

In gravitational fields when can you use the equation E_P = mgh?

Answer 3

Over small distances

When radial fields are approximately uniform

And g is approximately constant

Question 4

Why can’t SUVATs be used for radial gravitational fields?

Answer 4

SUVATs need a constant acceleration

Radial fields have a variable field strength and so a variable acceleration

Question 5

What are equipotentials and how are they related to field lines?

Answer 5

An equipotential has the same potential along that line

(So no work is done moving along the equipotential)

They are always perpendicular to field lines

Question 6

What is Newton’s Universal Law of Gravitation?

Answer 6

Force acting between two bodies is:

1. Directly proportional to the product of their masses (F∝m₁m₂)
2. Inversely proportional to the square of their separation (F∝1/r²)

Question 7

Define gravitational field strength and state its units

Answer 7

The force acting per unit mass on an object in a gravitational field

[NKg^-1] or [ms^-2]

Question 8

In the gravitational field strength equation what does M represent?

Answer 8

The mass of the object creating the field

Question 9

If the Earth is exerting a force on the rocket of 5000N,

What force is the rocket exerting on the Earth?

Answer 9

5000N also. An equal and opposite force from Newton’s 3rd Law

(Which has little effect on the Earth because it has so much more mass)

Question 10

How do you calculate the resultant gravitational field strength at a point between two bodies?

Answer 10

1. Calculate the field strength for each body in turn (ignoring the other one)
2. Calculate the difference between the field strengths (g is a vector)

Question 11

How do you you calculate the field strength (or force) neutral point between two bodies in a gravitational field?

Answer 11

Question 12

What is the definition of and the equation for absolute potential energy in a gravitational field?

Answer 12

The work done moving an object from infinity to that point in the field

Question 13

Why is gravitational potential energy always negative?

Answer 13

• Gravitational potential energy is 0 at infinite distance
• And decreases inwards as you move towards object creating field
• (So must go negative)

Question 14

What is gravitational potential?

Answer 14

The work done per unit mass moving an object from infinity to that point in a field

Question 15

In this equation for gravitational potential what object is represented by mass M?

Answer 15

The mass of the object creating the field

Question 16

Which astronaut has a greater loss in gravitational potential energy?

Answer 16

Neither. Potential energy (and potential) are scalar quantities so are unaffected by the path

Both decrease by 1440MJ

Question 17

What is the mistake here?

Answer 17

In the second stage the mass of the satellite must be used

(Not the Earth’s mass again)

Question 18

If a gravitational fields question uses the word ‘height’ what must you do?

Answer 18

Height is the distance above the surface

So you must add on the radius of the planet/star/object

Question 19

Why can’t two objects have a neutral point for gravitational potential? (or GPE)

Answer 19

Gravitational potential from both is negative

So they combine

To increase the magnitude of the potential

Question 20

When can you use these proportionality equations in Gravitational fields?

Answer 20

When the mass or masses are constant

Question 21

In gravitational fields What does a force-separation graph look like?

And what else does the graph tell you?

Answer 21

The area under the curve is the change in potential energy moving between the two separations

Question 22

In gravitational fields What does a field strength-separation graph look like?

And what else does the graph tell you?

Answer 22

The area under the curve is the change in potential moving between the two separations

Question 23

In gravitational fields What does a potential-separation graph look like?

And what else does the graph tell you?

Answer 23

The gradient of a tangent is the field strength at that point

Question 24

In gravitational fields What does a potential energy-separation graph look like?

And what else does the graph tell you?

Answer 24

The gradient of a tangent is the magnitude of the force at that point

Question 25

What is the equation for gravitational field strength within a planet?

(r ≤ R)

Answer 25

This part of the graph is linear as g ∝ r

Question 26

How do you derive the equation for gravitational field strength inside a planet?

Answer 26

• Use general equation for density (M/V)
• With V as the volume of a sphere (4/3πr³)
• Sub into general equation for field strength

Question 27

How do you derive Kepler’s 3rd Law? (r³ ∝ T²)

Answer 27

1. Equate centripetal force to force due to gravity
2. Substitute in angular speed formula (from circular motion)
3. Rearrange

Question 28

How do you derive the formula for the velocity of a satellite orbiting a planet or star?

Answer 28

1. Equate centripetal force to force due to gravity
2. Rearrange

Question 29

Which planet has the greatest orbital velocity and why?

Answer 29

Mercury

It is closest to Sun so smallest r

Question 30

How do you derive the formula for the escape velocity of a planet or star?

Answer 30

Question 31

In these 3 equations what does the mass refer to?

Answer 31

The mass of the object creating the field

Question 32

Why does a satellite not need to be above the escape velocity to reach low Earth orbit?

Answer 32

1. Escape velocity only applies to objects without engines (that can’t increase their KE)
2. Satellite isn’t escaping the field (so doesn’t need as much KE)

Question 33

How do you calculate the Kinetic Energy of a satellite orbiting a planet?

Answer 33

Substitute orbital velocity into equation for kinetic energy

Question 34

How do you calculate the total energy of an orbiting satellite?

Answer 34

Add the kinetic and potential energy together…

Question 35

What is the difference between a geosynchronous and geostationary orbit?

Answer 35

Both have orbital periods of 24 hours (the same as the Earth)

Question 36

How are geostationary and polar satellites different?

Answer 36

Geostationary satellites orbit above the same point of the equator and have an orbital period of 24 hours

Polar satellites orbit over the North and South pole with an orbital period of much less (around 2 hours)

Question 37

What are polar satellites used for?

Answer 37

• Communication for high latitude regions (close to the poles)
• Espionage (spying)
• Meteorology (weather)

Question 38

What are Geostationary satellites used for?

Answer 38

• Satellite television
• Mobile Phone Communications
• GPS