Waves (AS)

Question 1

What is phase difference?

Answer 1

The amount one wave lags behind another.

Question 2

What happens when a wave is reflected?

Answer 2

The wave is bounced back when it hits a boundary.

Question 3

What happens when a wave is refracted?

Answer 3

The wave changes direction as it enters a different medium.

The change in direction is a result of the wave slowing down or speeding up.

Question 4

Are electromagnetic waves transverse or longitudinal?

Answer 4

Transverse.

Question 5

In which direction do tranverse waves vibrate?

Answer 5

Perpendicular to the direction of energy transfer.

Question 6

In which direction do longitudinal waves vibrate?

Answer 6

Same direction as energy transfer.

Question 7

Are sound waves transverse or longitudinal?

Answer 7

Longitudinal.

Question 8

What is a polarised wave?

Answer 8

A wave that only oscillates in one direction.

Question 9

Can you polarise transverse waves?

Answer 9

Yes.

Question 10

Can you polarise longitudinal waves?

Answer 10

No.

Question 11

Polarisation is evidence that electromagnetic waves are ______. Physicists in 1808 thought that like was a _______ wave, and so were confused when light could be polarised. This suggested light was a ______ wave.

Answer 11

Polarisation is evidence that electromagnetic waves are (transverse). Physicists in 1808 thought that like was a (longitudinal) wave, and so were confused when light could be polarised. This suggested light was a (transverse) wave.

Question 12

If you hold two polarising filters at ______ ______ to each other, no _____ will get through.

Answer 12

If you hold two polarising filters at (right angles) to each other, no (light) will get through.

Question 13

Television and radio signals are ______. This is why you can ‘tune’ them, to align the waves accordingly.

Answer 13

Television and radio signals are (polarised). This is why you can ‘tune’ them, to align the waves accordingly.

Question 14

What is superposition?

Answer 14

When two or more waves pass through each other, and so the displacement of each wave is combined to make one large wave.

‘Superposition’ means ‘one thing on top of another thing’.

Question 15

A crest plus a crest gives a bigger crest. A trough plus a trough gives a bigger trough. What are these examples of?

Answer 15

Constructive interference.

Question 16

A crest plus a trough (of equal sizes) cancel each other out. What is this an example of?

Answer 16

Deconstructive interference.

Question 17

What is frequency?

Answer 17

Number of wave cycles occuring each second.

Question 18

Two sources are coherent if they have the same ______ and ______ and a ______ ______ ______ between them.

Answer 18

Two sources are coherent if they have the same (wavelength) and (frequency) and a (fixed phased difference) between them.

Question 19

What is a node?

Answer 19

A point of no displacement on stationary waves.

Question 20

Are two points with a phase difference of zero or a multiple of 360° in phase?

Answer 20

Yes

Question 21

Are two points with a phase difference of 180° and 360° in phase?

Answer 21

No, they’re exactly out of phase.

Question 22

When do waves deconstructively interfere?

Answer 22

Waves deconstructively interfere when they are in antiphase with each other, i.e 180° out of phase.

Question 23

When do waves constructively interfere?

Answer 23

Waves constructively interfere when they are in phase with each other.

Question 24

What is a stationary (standing) wave?

Answer 24

A stationary (standing) wave is the superposition of two progressive waves with the same frequency (wavelength), moving in opposite directions.

A wave that stores, but does not transfer, energy.

Question 25

What is an antinode?

Answer 25

A point of maximum displacement on a stationary wave.

Question 26

What is the first harmonic?

Answer 26

A stationary wave vibrating at the lowest possible frequency.

Two nodes.

Has a length of half a wavelength.

Question 27

What is the second harmonic?

Answer 27

Twice the frequency of the first harmonic.

Three nodes.

Has a length of 1 wavelength.

Question 28

What is the third harmonic?

Answer 28

Three times the frequency of the first harmonic.

Four nodes.

Has a length of 1 1/2 wavelengths.

Question 29

The frequency of the first harmonic, f, is:
f = (1/2L)√(T/μ)
What does L, T and μ represent?

Answer 29

f = (1/2L)√(T/μ)

L = string length in m
T = tension in string in N
μ = mass per unit length of string in kgm^-1

μ = m/L 
T = mg

Question 30

In order to observe a clear diffraction pattern, what kind of light source do you need?

Answer 30

Monochromatic (same wavelength and frequency, so the same colour) and coherent light source.

Lasers are a monochromatic and coherent light source.

Question 31

What is diffraction?

Answer 31

Diffraction is the spreading of waves as they pass through a gap of a similar size to their wavelength.

Question 32

What does diffracting white light produce?

Answer 32

A spectra of colours.

Question 33

White light is a ______ of different ______, each with different ______.

Answer 33

White light is a (mixture) of different (colours), each with different (wavelengths).

Question 34

What happens when you shine a white light through a single narrow slit?

Answer 34

All of the different wavelengths are diffracted by different amounts, and so you get a spectra of colours.

Question 35

In diffraction patterns, what are the areas of light and dark called?

Answer 35

Dark and bright fringes.

The central bright fringe is called the central maximum.

Question 36

What precautions should you take whilst using a laser?

Answer 36

Whilst using a laser, you should:

1. Never shine the laser towards a person
2. Wear laser safety goggles
3. Avoid shining the laser beam at a reflective surface.
4. Have a warning sign on display
5. Turn of the laser when it’s not needed

Question 37

Are interference patterns more or less defined/sharp when you use a higher diffraction grating?

Answer 37

Interference patterns are more defined/sharp when you use a higher diffraction grating because there are so many beams reinforcing the pattern.

Question 38

What is the line of maximum brightness in diffraction patterns referred to as?

Answer 38

The line of maximum brightness in diffraction patterns is referred to as the ‘zero order line’.

The lines either side of the zero order line are the first order lines and so on.

Question 39

What conclusions can you draw from dsinθ = nλ?

Answer 39

dsinθ = nλ

1. If λ is bigger, sinθ is bigger, so θ is bigger. This means that the larger the wavelength, the more spread out the pattern will be.
2. If d is bigger, sinθ is smaller. This means that the less lines per mm of a grating, the less spread out the diffraction pattern will be.
3. If for a certain value of n you get a value for more than 1 for sinθ then you know that order doesn’t exist.

Question 40

Why does light slow down when it enters materials?

Answer 40

Light slows down in materials because it interacts with the particles in them.

The more optially dense a material is, the more light slows down when it enters it.

Question 41

What is the absolute refractive index of a material?

Answer 41

The absolute refractive index of a material is a measure of optical density.

It is found from the ratio between the speed of light in a vacuum, c, and the speed of light in that material, cs.

n = c/cs

Question 42

What is Snell’s Law?

Answer 42

Snells Law:

n1sinθ1 = n2sinθ2

Question 43

How do step-index optical fibres work?

Answer 43

Step-index optical fibres themselves have a high refractive index but are surrounded by cladding with a lower refractive index to allow total internal reflection.

Cladding also protects the fibre from scratches which could let light escape.

Question 44

What can cause a signal travelling through an optical fibre to degrade?

Answer 44

A signal (a stream of pulses of light) travelling down an optical fibre can be degraded by absorption or by dispersion.

Signal degradation can cause information to be lost.

Question 45

How does absorption of a signal travelling through an optical fibre degrade the signal?

Answer 45

As the signal travels, some of its energy is lost through absorption by the material the fibre is made from.

This energy loss results in the amplitude of the signal being reduced.

Question 46

How does modal dispersion of a signal travelling through an optical fibre degrade the signal?

Answer 46

The rays which take a longer path take longer to reach the other end than those that travel down the middle of the fibre.

Question 47

How can you stop modal dispersion from occuring in an optical fibre?

Answer 47

A single-mode fibre only lets light take one path, so it stops modal dispersion.

Question 48

How does material dispersion of a signal travelling through an optical fibre degrade the signal?

Answer 48

Material dispersion - light consists of different wavelengths that travel at different speeds in the fibre.

This causes some light wavelengths to reach the end of the fibre faster than others.

Question 49

How can you stop material dispersion from occuring in an optical fibre?

Answer 49

Using monochromatic light can stop material dispersion.

Question 50

What does dispersion cause in optical fibres?

Answer 50

Both types of dispersion (modal and material) lead to pulse broadening.

The signal sent down the fibre is broader at the other end.

Broadened pulses can overlap each other and confuse the signal.

Question 51

What can be used to reduce signal degradation in optical fibres?

Answer 51

An optical fibre repeater can be used to boost and regenerate the signal every so often, which can reduce signal degradation cause by both absorption and dispersion.

Question 52

Define coherence.

Answer 52

Coherent waves have a fixed phase difference and the same frequency and wavelength.

FIXED PHASE DIFFERENCE, SAME F & λ

Question 53

Why is a laser useful in showing interference and diffraction?

Answer 53

Lasers produce monochromatic light (same λ) so diffraction and interference patterns are more defined.

Question 54

What was Young’s double slit-experiment?

Answer 54

• Single light source is directed towards two slits
• These act as coherent light sources
• Light interferes constructively and deconstructively to produce a diffraction pattern

Question 55

What is the order of colours when you direct a white light at a single slit to produce a diffraction pattern?

Answer 55

Diffraction pattern using white light:

• Central white maximum at the zero order
• Flanked by two spectral fringes, violet closest to 0 order and red furthest

Question 56

Why is a diffraction pattern formed when a light source is passed through a single slit?

Answer 56

• The light diffracts as it passes through the slit
• Where the waves are in phase, constructive interference occurs, making bright fringes
• Where the waves are completely out of phase, deconstructive interference occurs, making dark fringes.

Question 57

What is the equation for fringe spacing?

Answer 57

Fringe Spacing

w = λD / s

w = fringe spacing
λ = wavelength
D = distance from slits to screen
s = spacing between slits

Question 58

What is modal dispersion?

Answer 58

Modal Dispersion: Light rays enter the fibre at different angles, and so take different paths.

Question 59

How can you prevent modal dispersion?

Answer 59

A single-mode fibre only lets light take one path, so it stops modal dispersion.

Question 60

When does total internal reflection occur?

Answer 60

Total internal reflection occurs when:

• When light is at a boundary to a less optically dense medium
AND
• Angle of incidence is greater than the critical angle

Question 61

How can you stop material dispersion?

Answer 61

Using monochromatic light can stop material dispersion.

Same λ, and so travel at the same speed.

Question 62

What is the equation for diffraction grating?

Answer 62

dsinθ = nλ

d = diffraction grating
sinθ = angle between 0 order and nth order
n = order maximum
λ = wavelength

Question 63

What is pulse broadening?

Answer 63

Pulse broadening

• When the recieved signal is wider than the original.
• Can cause the overlap of signals leading to information loss.

Question 64

What path does a light ray take when the angle of incidence is equal to the critical angle?

Answer 64

It goes along the boundary.

I.e., the angle of refraction is 90°.