4.4

Question 1

what are the two types of waves?

Answer 1

transverse and longitudinal

Question 2

define longitudinal waves

Answer 2

waves which have oscillations parallel to the direction of the wave (or wave propagation)

Question 3

define transverse waves

Answer 3

waves which have oscillations perpendicular to the direction of the wave (or wave propagation)

Question 4

define displacement

Answer 4

the distance a point on a wave has moved from its undisturbed/equilibrium/rest position can be positive OR negative, measured in metres

Question 5

define amplitude

Answer 5

the maximum displacement, the distance from a peak or trough to its rest position, measured in metres

Question 6

define wavelength

Answer 6

the distance between two successive identical points on a wave that has the same pattern of oscillation

Question 7

define time period

Answer 7

the time it takes for one complete oscillation to occur at any point

Question 8

define phase difference

Answer 8

the difference in phase angle by which one wave lags behind another, measured in radians or degrees

Question 9

define frequency

Answer 9

the number of complete oscillations that pass a point per unit time

Question 10

define wave speed

Answer 10

the distance the wave travels per unit time

Question 11

define wave speed

Answer 11

the distance the wave travels per unit time

Question 12

what is the equation for frequency?

Answer 12

f = 1/T 
(T = period)

Question 13

outline an experiment using an oscilloscope to determine the frequency of a wave

Answer 13

• an oscilloscope displays a voltage-time signal from either a microphone or a signal generator (microphone converts sound waves into electrical signals)
• the screen is split into divisions, the voltage on the y-axis (controlled by GAIN DIAL, volts per division), time on the x-axis (controlled by TIMEBASE DIAL, seconds per division)
• use frequency = 1/t (t=period of wave in seconds) to calculate frequency

(note if the time base is turned off, the wave no longer moves across the screen making it easy to look at the intensity of the wave)

Question 14

in a graphical representation of a longitudinal wave, what parts are the peaks and troughs?

Answer 14

rarefaction = trough (where the lines far apart)
compression = peak (where the lines bunch up)

Question 15

what is the reflection and what is the key rule?

Answer 15

reflection occurs when a wave bounces off a surface and changes direction when it hits a boundary, the angle of incidence is ALWAYS equal to the angle of reflection

Question 16

what is refraction?

Answer 16

refraction occurs when a wave changes speed and direction as it travels through a different medium, this depends on how optically dense the medium is (bending of a wave)

Question 17

what is diffraction?

Answer 17

the spreading of a wave through a small gap or around an obstacle, the effect is most significant when the gap width is equal to the wavelength, noticeable effects when the gap width is several wavelengths wide

Question 18

what is plane polarisation? what types of waves can be polarised?

Answer 18

plane polarisation is when a wave is restricted so that it only oscillates in one direction, only TRANSVERSE waves can be polarised

Question 19

what is the wave speed equation?

Answer 19

v = fλ

with questions concerning EM radiation, all EM waves travel at c = 3 x10^8

Question 20

outline an experiment using a ripple tank to investigate wave effects (reflection, diffraction and refraction)

Answer 20

First, set up a ripple tank of water with a light directly above it and a straight bar motor connected to a paddle, the wavefronts will be visible on the screen below the tank.
REFLECTION:
-to investigate reflection place a barrier in the tank at an angle to the wavefronts, the waves will reflect off the barrier and travel in a different direction to the way they arrived, remember the angle of incidence θi = angle of reflection θr
DIFFRACTION:
-to investigate diffraction place an object in the ripple tank to create a barrier with a gap in the middle of it, this gap can be varied to see the effects this has on how the waves spread through the tank, remember when the gap is close to or the same size as the wavelength = most diffraction
REFRACTION:
-to investigate refraction a glass sheet can be used to decrease the water depth and produce a region with a different wave speed

Question 21

outline an experiment using polarising filters to polarise visible light

Answer 21

place a light source in front of two polarising filters (unpolarised light is in all directions), keep the first filter in a fixed position and rotate the second to change the intensity from maximum light to no light, rises and falls as the angle is changed remember MALUS’ LAW

Question 22

how does polarisation work?

Answer 22

just like vectors, you can think of the transmission axis of the rotating filter as having a vertical and horizontal component, the larger the vertical component, the more vertically polarised light will pass through the filter.
as the second filter is rotated horizontally, less light will get through it as the vertical component of the second filter’s transmission axis decreases which means the intensity through the second filter decreases

Question 23

what is Malus’ law and what does it tell you?

Answer 23

I = Io x cos^2θ
-it tells you the intensity of plane polarised light that passes through a filter
I = final intensity after passing through second filter
Io = initial max intensity
θ = angle between the first and second filter

Question 24

outline an experiment to observe polarisation of microwaves

Answer 24

• place a metal grille in between a microwave transmitter and receiver (opposite sides of grille), connect the receiver to an ammeter
• the microwave transmitter produces vertically plane-polarised radiation
• the metal grille absorbs radiation of the same plane as the radiation meaning when the metal grille is horizontal very few of the microwaves will be absorbed so the ammeter will show a high output, when the metal grille is vertical all of the microwaves will be absorbed meaning the ammeter will show no output

Question 25

what is the formula for intensity of a progressive wave and what is the relationship between intensity and amplitude?

Answer 25

intensity = power/area
intensity is directly proportional to amplitude squared
this comes from the fact that intensity is proportional to energy and the energy of a wave depends on the square of the amplitude

Question 26

what are the main properties of EM radiation?

Answer 26

• they all travel at c (3x10^8m/s)
• they are transverse
• they consist of an electric and magnetic field that are at right angles to each other and the direction of wave travel
• they can be refracted, reflected, diffracted, polarised and can undergo interference

Question 27

what is the order of the EM spectrum?

remember Hammond’s mnemonic

Answer 27

Radio, Micro, Infrared, Visible, Ultraviolet, X-Ray, Gamma

Question 28

order of magnitude for radio

Answer 28

10^6 - 10^-1 m

Question 29

order of magnitude for micro

Answer 29

10^-1 - 10^-3 m

Question 30

order of magnitude for infrared

Answer 30

10^-3 - 7x10^-7 m

Question 31

order of magnitude for visible

Answer 31

7x10^-7 - 4x10^-7 m

Question 32

order of magnitude for ultraviolet

Answer 32

4x10^-7 - 10^-8 m

Question 33

order of magnitude for x-rays

Answer 33

10^-8 - 10^-12 m

Question 34

order of magnitude for gamma

Answer 34

10^-12m - 10^-16 m

Question 35

what is the formula for refractive index?

Answer 35

n = c/v
c = speed of light in a vacuum 
c = speed of light in the medium

Question 36

what does the refractive index tell us?

Answer 36

it tells us the ratio of the speed of light in the medium compared to the speed of light in a vacuum (measures how much the material slows down light)

Question 37

if something has a high refractive index what does that mean about the speed of light in the medium?

Answer 37

slow speed

Question 38

if something has a low refractive index what does that mean about the speed of light in the medium?

Answer 38

high speed

Question 39

how does light bend when it moves into a medium with a low refractive index (speeds it up)?

Answer 39

light bends AWAY from the normal

Question 40

how does light bend when it moves into a medium with a high refractive index (slows it down)?

Answer 40

light bends TOWARDS the normal

Question 41

what is snell’s law?

Answer 41

n1sinθ1 = n2sinθ2
n1 = refractive index of first medium 
θ1 = angle of incidence 
n2 = refractive index of first medium 
θ2 = angle of refraction 

nsinθ = CONSTANT at a boundary where θ is the angle to the normal

Question 42

what is the total internal reflection and when does it occur?

Answer 42

when the light is reflected back into the material and it occurs when the angle of refraction is above 90 degrees and therefore the angle of incidence is more than CRITICAL (when it is equal to critical is will travel along the boundary of the material at 90 degrees)

Question 43

what is the critical angle equation?

Answer 43

sinC = 1 / n
(n = refractive index of the material)
this comes from snells law as n2 = 1 because its in air and θ2 is 90 degrees (angle of refraction) making sin90 = 1

Question 44

outline an experiment to investigate the total internal reflection

-

Answer 44

shine a light ray into the curved face of a semi-circular glass block so that it always enters at right angles to the edge (this means the ray won’t refract as it enters the block, just when it leaves from the straight edge)

• vary the angle of incidence until the light beam refracts so much that it exits the block along the straight edge, this angle of incidence is critical
• if you increase the angle of incidence so its greater than C, you’ll find the ray is reflected from the straight edge of the block (total internal reflection occurs)

Question 45

what is the principle of superposition of waves?

Answer 45

it states that when two or more waves of the same type meet, the resultant wave can be found by the vector addition of the displacements of the individual waves

Question 46

outline an experiment to investigate two-source interference with sound waves

Answer 46

• connect two speakers to the same oscillator (so the waves are coherent and in phase) and place them in line with each other
• walk slowly across the room in front of them
• you will hear varying volume of sound, at the points where the sound is loudest, the path difference is a whole wavelength (nλ)
• at points where the sound will be quietest the path difference is an odd number of half wavelengths (n+0.5λ)

Question 47

outline an experiment to investigate two-source interference with microwaves

Answer 47

(similar to sound waves & light)

• use a microwave signal generator and attach it to two transmitter cones to produce two coherent wave sources
• instead of a screen you will use a microwave receiver probe
• if you move the probe along the path of interference (straight) you’ll get an alternating pattern of strong and weak signals (just like dark and bright fringes in light experiment, or varying sound in sound experiment)

Question 48

what is interference?

Answer 48

interference is a phenomenon in which two waves superpose to form a resultant wave of greater, lower, or the same amplitude, can be constructive or destructive

Question 49

what is path difference?

Answer 49

refers to the difference between the distances travelled by two waves arriving at the same point, measured in λ (metres)

Question 50

what is constructive interference and what is the rule for path difference when this occurs?

Answer 50

when the two waves superpose constructively to produce a wave with larger amplitude, can be total constructive or partially destructive
rule = nλ (whole number of half wavelengths)

Question 51

what is constructive interference and what is the rule for path difference/phase difference when this occurs?

Answer 51

when the two waves superpose constructively to produce a wave with larger amplitude, can be total constructive or partially constructive
rule 1 = nλ (whole number of half wavelengths)
rule 2 = 0, 2π, 4π…

Question 52

what is destructive interference and what is the rule for path difference/phase difference when this occurs?

Answer 52

when the two waves superpose destructively to produce a wave with a smaller amplitude, can be total destructive (if the two waves are in anti-phase and have the same amplitude they will cancel each other out) or partially destructive
rule 1 = n +0.5λ (odd number of half wavelengths)
rule 2 = π, 3π, 5π

Question 53

why does a whole number of wavelengths result in constructive interference?

Answer 53

this is because a whole number of wavelengths in path difference shows that there is no phase difference (results in the waves arriving at the same point in phase)

Question 54

what was Young able to do and find out from his double-slit experiment?

Answer 54

Young was able to find the wavelength of light and prove it wave-like properties

Question 55

what is the formula Young used to calculate the wavelength of light?

Answer 55

λ = ax/d

where a = slit spacing, x = fringe spacing, d = distance from slits to screen

Question 56

what were the issues with Young’s Double Slit Experiment and what solutions are there?

Answer 56

-the fringes were very small and therefore the fringe spacing was very hard to measure fringe spacing
-you could increase the fringe spacing by increasing d but this would make it more faint due to decreased intensity
-to reduce percentage error in the fringe spacing you could measure several fringes and then divide by the number of fringe spacings between them
HARD TO OBTAIN ACCURATE VALUE FOR λ

Question 57

what is a diffraction grating?

Answer 57

it is a piece of optical equipment made from glass, onto which many thousands of very thin, parallel and equally spaced grooves/slits have been made

Question 58

outline and explain the diffraction grating experiment

Answer 58

• set up a laser with monochromatic light (or use a filter)
• place a diffraction grating in front
• the multiple slits will diffract the light into a clear interference pattern with bright and dark fringes on the screen

Question 59

explain the orders in diffraction grating experiment

Answer 59

the line of maximum brightness directly at the centre of the screen is the zero order, the lines on either side of the central one are the second order, then third and so on…

Question 60

what would differ if you shined white light as opposed to monochromatic light through a diffraction grating?

Answer 60

-you would get produce a colour spectra,
the zero order would be white, the next orders (first, second and so on) would be a spectrum of all the colours
-red refracts the MOST and would be furthest away, violet would be closet to the centre

Question 61

what is the equation linked to diffraction grating?

Answer 61

dsinθ = nλ
d = distance between slits (slit separation) 
θ = the angle the beam makes with the grating 
n = the order 
λ = wavelength

Question 62

what is a node?

Answer 62

a point on the standing/stationary wave where the amplitude is zero

Question 63

what is an antinode?

Answer 63

a point on the standing/stationary wave where the amplitude is at a maximum

Question 64

what are the key differences between stationary and progressive waves?

Answer 64

progressive waves travel and carry energy whereas stationary waves are fixed in position and instead store energy

Question 65

outline and explain Young’s Double-Slit experiment using visible light

Answer 65

• set up a laser source with monochromatic (red) light
• the light will pass through a single slit (with gap width comparable to wavelength) and gets diffracted to ensure the waves are coherent
• the waves reach the double slit where diffraction occurs again producing two coherent wave sources, these waves overlap and interfere
• the progressive waves will reach the screen, where they arrive in phase there will be red fringes and where the arrive out of phase there will be no light (appear dark, dark fringes)