P8.3 - Beyond Earth

Question 1

What is the difference between an absorption spectrum and an emission spectrum?

Answer 1

Absorption spectrum - A continuous spectrum with dark lines corresponding to particular frequencies being absorbed by an atom.

Emission spectrum - A set of frequencies of radiation emitted by an atom when excited electrons move to lower energy levels.

Question 2

What is the Doppler effect?

Answer 2

The physical phenomena by which there is a change in the observed frequency/wavelength of wave, due to relative motion between observer and source.

Relative motion - Source moving, OR observer moving, OR both source and observer moving.

Question 3

What happens, in terms of the Doppler effect, when a sound source moves towards you?

Answer 3

When the sound source moves towards you, wave peaks move closer together, the wavelength decreases and the observed frequency/pitch of sound increases.

Question 4

What happens, in terms of the Doppler effect, when a sound source moves away from you?

Answer 4

When the sound source moves away from you, wave peaks move further apart, the wavelength increases and the observed frequency/pitch of sound decreases.

Question 5

Why is the the Doppler effect with light waves very difficult to observe?

Answer 5

The light waves have a much smaller wavelength than sound waves.

The Doppler effect is observed when the relative motion between the observer and the source is very large.

Question 6

What is red-shift and what does it imply?

Answer 6

Red shift - The shift in wavelength of the light emitted from a source to longer wavelengths.

Implies - That the source is moving away from us.

Question 7

What is blue shift and what does it imply?

Answer 7

Blue shift - The shift in wavelength of the light emitted from a source to shorter wavelengths.

Implies - That the source is moving towards us.

Question 8

Describe how the red-shift of distant galaxies provides some evidence for the The Big Bang Theory.

Answer 8

OBSERVATIONS
Light from distant galaxies is red-shifted.
The further away the galaxy, the greater the red-shift.

CONCLUSIONS
Galaxies are moving away from us.
The further away the galaxy, the faster it is moving away.

Thus, if galaxies are moving away from each other, this suggests that at one point, all matter must have existed at a single point in space - One piece of evidence for the big bang.

Question 9

How do we know light from distant galaxies are red shifted?

Answer 9

The absorption spectra of stars contain black lines.

These black lines correspond to very specific wavelengths of light absorbed by certain atoms in the star.

Hence, all spectra from starts contain a series of very specific black lines (distinct pattern of separated lines).

These black lines are seen shifted in the spectra from distant stars towards longer wavelengths.

This implies that light from distant stars have undergone a Doppler shift.

Question 10

Describe how cosmic microwave background radiation provided evidence for the Big Bang theory.

Answer 10

At the beginning of the universe, all the energy of the universe would have manifested as very short wavelength gamma waves.

As the universe expanded, this gamma radiation would have stretched out to longer and longer wavelengths… and is now microwave radiation.

The fact that the microwaves uniformly/evenly fill the universe suggests they all started off from a single point (filling the universe as the universe expanded).

The steady state theory cannot explain this fact, only the Big Bang Theory can.

Question 11

What is/are:
The sun
Planets
Moons
Minor planets
Comets

Answer 11

The sun - Star at the centre of the solar system.

Planets - Spherical bodies that orbit the sun.

Moons - Spherical bodies that orbit planets.

Minor planets - Small spherical objects that orbit the sun.

Comets - Objects made of dust/ice that orbit the Sun with long period, elliptical orbits.

Question 12

What are the inner planets and what are they made of?

Answer 12

Mercury - Atmosphere very thin, no moon

Venus - Atmosphere is mainly carbon dioxide and it rains sulfuric acid, no moon

Earth - One moon

Mars - Atmosphere very thin, two moons

• Rocky
• All have an atmosphere

Question 13

What are the inner planets and their properties?

Answer 13

Gas giants - Jupiter and Saturn
Ice giants - Uranus and Neptune

All have rings and a lot of moons.

Question 14

What is between Mars and Jupiter?

Answer 14

An asteroid belt - A band of dust and larger pieces of rock left over from the formation of the solar system and orbits the sun.

Question 15

Describe the beginning of the life cycle for all stars.

Answer 15

• Dust and gas gather under gravity to form a protostar.

- Once the protostar has become hot and dense enough, nuclear fusion begins and the star becomes a main sequence star.

Question 16

Describe the middle stages in the life cycle for all stars.

Answer 16

• A star is stable during its main sequence.
• The radiation pressure outwards from nuclear fusion balances the gravitational attraction inwards (there is equilibrium/stability).
• Eventually, the hydrogen nuclei will run out.
• The star will cool, and its radiation pressure drops.
• The gravitational force collapses the star, causing it to heat up again.
• The fusion of heavier elements begins.
• The energy from fusion increases. Therefore, the radiation pressure increases. The star becomes either a red giant or a red super giant.

Question 17

What is the ending steps for the life cycle of a small star (a red giant)?

Answer 17

• The nuclei for fusion run out.
• Fusion slows down.
• Radiation pressure decreases.
• The gravitational force collapses star.
• The star heats up becomes a white dwarf.
• The star eventually cools down to form a black dwarf.

Question 18

What is the ending steps for the life cycle of a large star (a red super giant)?

Answer 18

• Lots of heavier nuclei fused together to release lots of energy.
• There is a large increase in radiation pressure outwards. This is much larger than the gravitational pull inwards.
• The star explodes in a supernova.
• A very dense neutron star forms.
• If the neutron star is very dense, it could become a black hole.

Question 19

What is the life cycle for a low mass star?

Answer 19

Protostar - Main sequence star - Red giant - White dwarf - Black dwarf

What is the life cycle for a high mass star?
Protostar - Main sequence star - Red super giant - Supernova - Neutron star - If these is a very high density - Black hole

Question 20

Explain why the sun started to shine.

Answer 20

Once the sun became hot and dense enough under gravity, nuclear fusion of nuclei began, releasing energy, causing the sun to emit EM radiation and shine.

Question 21

Explain why the sun is not expanding?

Answer 21

There is a balance between the force of gravity inwards and the radiation pressure from nuclear fusion outwards, that ensures the sun does not expand or contract.

Question 22

Suggest why the outer planets have many more moons than the inner planets.

Answer 22

Outer planets have more mass than the inner planets.

Thus, their gravitational fields and stronger.

When the solar system was forming, the outer planets attracted more dust/gas towards them.

This dust/gas came together under gravity to form the many moons of the outer planets.

Question 23

What type of star is our sun?

Answer 23

A small star.

Currently a main sequence star.

Question 24

What is a satellite?

Answer 24

A satellite is any body that orbits a planet or star.

Question 25

What are examples of natural satellites and artificial satellites?

Answer 25

Natural satellites - The moon is a satellite of Earth. Earth is a satellite of the sun.

Artificial satellites - Communication satellites in orbit about Earth.

Question 26

What are the two types of orbit that a satellite may orbit the Earth in?

Answer 26

Satellites that orbit the Earth do so in one of two types of orbit. Either a geostationary orbit or a polar orbit.

Question 27

Give information about satellites that orbit the Earth in a geostationary orbit.

Answer 27

Orbital time period = 24 Hours.

Orbital height = 36,000km.

The satellite is launched above the equator. The satellite remains in a fixed position relative to Earth. This is also why satellite dishes down a road face the same way.

Examples = Communications/GPS, television.

Question 28

Give information about satellites that orbit the Earth in a polar orbit.

Answer 28

Orbital time period = 100 minutes.

Orbital height = 2000km.

The satellites are launched about the poles. Therefore, the satellites rotate about the Earth once every 100 minutes, as the Earth rotates under it. The satellite can scan the entire surface of the Earth, very quickly.

Examples = Weather, spy satellites.

Question 29

Why must you get the correct satellite orbit velocity?

Answer 29

The velocity you launch a satellite at (in its orbit… not on the way up to space!) will determine the radius the satellite orbits the Earth at, and hence the time period of orbit.

Question 30

What is an elliptical orbit?

Answer 30

Almost all planets orbit their star in an elliptical orbit.

An elliptical orbit differs from a circular one in that its radius isn’t fixed.

However, at any given point in the orbit, we can treat the planet as moving in a circular orbit of a given radius.

Question 31

Explain the idea of centripetal force?

Answer 31

A body in a circular orbit is constantly accelerating, as the direction of its velocity is constantly changing.

Hence, a resultant force must be acting upon a planet orbiting its star.

A resultant force that causes a body to perform circular motion is known as the centripetal force.

The centripetal force for a planet is provided by the gravitational attraction of its star.

Question 32

Explain how the speed of a satellite never changes.

Answer 32

The centripetal force/gravitational attraction always attracts towards the centre of the circular motion/orbit.

The centripetal force on any body always acts perpendicular to the body’s velocity.

Therefore, the speed of the body never changes, just the direction.

Question 33

What is a stable orbit?

Answer 33

A stable orbit maintains a constant radius about the body its orbiting.

Question 34

What happens if a satellite moves too slow or too fast?

Answer 34

If a satellite moves too slow, gravitational attraction will put it in.

If a satellite moves too fast, gravitational attraction is not great enough to hold onto the body and it flies away.

Question 35

What depends on the velocity for a satellite in order for it to maintain a stable orbit?

Answer 35

The distance it is away from the Earth.

The further away a body is from the body it orbits, the slower its velocity needs to be to maintain a stable orbit, the longer its time period.

Question 36

What happens the greater the temperature of a body?

Answer 36

The greater the temperature of a body, the faster the particles vibrate. This means that EM waves of greater frequency are emitted. This is why bodies that glow blue are hotter than those that glow red.

Question 37

When will the temperature of a body increase and increase?

Answer 37

If a body absorbs more radiation that it emits, its temperature will increase.

If a body emits more radiation that it absorbs, its temperature will decrease.

Question 38

Describe the intensity of radiation at each frequency against

Answer 38

A hotter object emits more radiation of a higher frequency and less radiation of a lower frequency.

The graph for a hot star peaks over a higher frequency than the graph for a cool star.

The intensity at each frequency is higher for a hot star than a cold one.

Question 39

How does the Earth’s atmosphere affect the temperature of the Earth?

Answer 39

The Earth absorbs radiation from the sun and emits radiation into space.

The Earth’s atmosphere reflects some of the radiation back to Earth.

The Earth absorbs more radiation (via the greenhouse effect) from the sun than it emits back into space.

Hence, the temperature of the Earth is increasing.

Question 40

Describe the structure of the Earth.

Answer 40

The centre of the Earth is about 6370km below the Earth’s surface.

The Earth has a solid inner core and a liquid outer core.

The mantle is almost entirely solid, but it can flow.

The crust (which we live on) is solid.

Question 41

What is the study of Earthquakes known as?

Answer 41

The study of earthquakes is known as seismology.

Question 42

When do earthquakes occur and what are seismic waves?

Answer 42

Earthquakes originate in the Earth’s crust and occurs when forces inside the Earth become large enough to break and move layers of rock.

The energy transferred during an Earthquake creates shockwaves, seismic waves.

Seismic waves travel through the Earth and across the surface of the Earth.

Question 43

What is the focus and epicentre of earthquakes?

Answer 43

The point where the seismic wave originates is called the focus.

The nearest point on the surface to the focus, is known as the epicentre of the earthquake.

Question 44

How are earthquakes recorded?

Answer 44

Earthquakes are recorded by detectors on the surface of the Earth, known as seismometers.

Question 45

What are the two different types of seismic waves?

Answer 45

1 - Primary waves (P Waves)

2 - Secondary waves (S Waves)

Question 46

Describe primary waves (P Waves).

Answer 46

• Cause initial tremors lasting about 10 minutes.
• Longitudinal waves that push and pull the Earth.
• Can travel through solids and liquids.

Question 47

Describe secondary waves (S Waves).

Answer 47

• Follows primary waves with more tremors a few minutes after.
• Transverse waves that shake up and down the Earth.
• Cannot travel through liquids.

Question 48

What happens to P and S waves as they travel through the Earth’s crust?

Answer 48

P and S waves refract/bend slowly as they travel through the solid crust. This is because the density of the crust slowly changes as you travel further into the Earth.

Question 49

What happens to P and S waves at the boundary between the mantle and the outer core?

Answer 49

At the boundary between the mantle and the outer core, the P and S waves refract a lot, because their speed suddenly changes a lot. This is because there is a large difference in density between the solid mantle and liquid outer core.

Question 50

Why are S waves not detected on the other side of the Earth?

Answer 50

S waves cannot travel through the liquid core, so are not detected on the other side of the Earth, producing S-wave shadow zones.

Question 51

How a P-wave shadow zones created?

Answer 51

P waves are refracted a lot as they cross the mantle/outer core boundary, creating regions where they are not detected, producing P-wave shadow zones.

Question 52

Explain how seismic waves detected around the world show that part of the Earth is liquid.

Answer 52

P-waves are longitudinal and can travel through solids and liquids.

S-waves are transverse and can only travel through solids.

Following an earthquake, P-waves are detected on the other side of the Earth, but S-waves are not detected.

This implies S-waves were unable to pass through part of the Earth.

Part of the Earth must therefore be liquid.

Question 53

Why do the path of waves in the mantle curve and what does this tell you about the mantle?

Answer 53

The waves refract/bend as they travel through the Earth. Since refraction is a wave phenomenon that only occurs when waves cross the boundary between two media, we can tell that the mantle contains layers of different densities, such that boundaries between media exist, giving rise to refraction.