physics paper 2 waves

Question 1

wavelength?

Answer 1

the distance from one peak to the next

Question 2

frequency?

Answer 2

number of complete waves there are per second passing a certain point- 1Hz is 1 wave per second

Question 3

amplitude?

Answer 3

the maximum displacement of a wave from rest to crest

Question 4

the period (T)?

Answer 4

the time it takes for 1 complete wave to pass a point

Question 5

frequency f=

Answer 5

1/T(ime period)

Question 6

wave speed (m/s)=

Answer 6

frequency (Hz) x Wavelength (m)

Question 7

transverse waves=

Answer 7

the vibrations are perpendicular to direction of energy transferred

Question 8

longitudinal waves=

Answer 8

the vibrations are parallel as the direction of energy transferred

Question 9

transverse wave examples

Answer 9

em waves
slinky spring moved up and down
waves on strings
ripples on water

Question 10

longitudinal wave examples

Answer 10

sound and ultrasound
shock waves
slinky spring pushed at end

Question 11

what does energy transfer?

Answer 11

information without transferring matter

Question 12

what does refraction mean?

Answer 12

the waves go through the new material but change direction

Question 13

what are the 7 types of EM waves

Answer 13

radio
micro
infrared
visiblelight
ultraviolet
x-rays
gamma rays

Question 14

what are EM waves in order of?

Answer 14

increasing frequencies and decreasing wavelength

Question 15

uses of radiowaves

Answer 15

1) long-wave radio as long wavelengths diffract around the earth
2) TV and FM radio broadcasting-short wavelengths- reception only in direct sight of transmitter as don’t diffract
3) short-wave radio signals are reflected off ionosphere-an electrically charged layer in Earth’s upper atmosphere so can be received at long distances from the transmitter

Question 16

uses of microwaves

Answer 16

1)satellite communication- which need to pass through watery atmosphere without being absorbed
2) for satellite TV signal from transmitter is transmitted into space -picked up bu satellite receiver dish orbiting and transmits signal back to Earth in diff directions
3)mobile phones
4) remote sensing satellites to monitor oil spills, movement of icebergs
5) microwave ovens-cooking-diff wavelength to communications
absorbed by water molecules in food penetrate few before being absorbed. the energy is conducted or convected to other parts of the food

Question 17

uses of infrared

Answer 17

1-heating-electrical heaters radiate IR for warmth

2-night-vision- turns into electrical signals which are displayed on a screen

Question 18

uses of UV

Answer 18

1-fluorescent lamps-absorbed and visible light is emitted
2-killing bacteria in water purification
3-killing bacteria in sterilisation of equipment

Question 19

uses of x-rays

Answer 19

see inside things- medical scans- radiation is directed through object or body onto detector plate-brighter bits are where x-rays can’t get through:bone

Question 20

uses of gamma

Answer 20

1-sterilising medical equipment-kills microbes

2- sterilising food-kills microbes keeps food fresh for longer without freezing

Question 21

uses of visible light

Answer 21

1)optical fibres- bouncing waves off sides of a very narrow core-enters at a certain angle and reflected until emerges at the other end
-used for telephone and broadband internet cables
- medical purposes to see inside body
2) photography- cameras use a lens to focus visible light onto a light-sensitive film from a sensor
the lens aperture controls how much light enters the camera
the shutter speed is how long the film or sensor is exposed to light

Question 22

dangers of microwaves and way to protect from it

Answer 22

heat human body tissue- have similar frequency to the vibrations of molecules so increase these=internal heating
- microwave ovens need to have shielding to prevent waves reaching user

Question 23

dangers of infrared and way to protect from it

Answer 23

skin burns- make surface molecules of substances vibrate=heating effect
- use insulating materials to reduce amount of IR reaching your skin

Question 24

dangers of ultraviolet and way to protect from it

Answer 24

damage surface cells
causes blindness- it is ionising so carries enough energy to know electrons off atoms= cell mutation or cancer
- wear sunscreen with UV filters
-stay out of strong sunlight

Question 25

dangers of gamma and way to protect from it

Answer 25

cell mutation leading to tissue damage or cancer- very high frequency waves ionising and penetrate far into body

• radioactive sources of gamma should be kept in lead-lined boxes
• exposure time should be as short as possible

Question 26

reflection of visible light means?

Answer 26

allows us to see all objects-light bounces off them into our eyes

Question 27

what’s a diffuse reflection?

Answer 27

when light reflects off an uneven surface such as paper and the light reflecs at all different angles

Question 28

angle of incidence=

Answer 28

angle of reflection defined between i and dotted normal

Question 29

what’s a virtual image?

Answer 29

when the light rays bouncing off an object onto a mirror are diverging so the light from the object appears to be coming from a different place

Question 30

how do EM waves move in dense media?

Answer 30

slower

Question 31

how can you experiment with refraction using a light source and a rectangular block?

Answer 31

1-put block on paper
2- shine a light ray at an angle into the block-some light is reflected but most passes through the glass and is refracted
3- trace the incident and emergent rays onto the paper and remove the block. draw in the refracted ray by joining the ends of the two rays
4-should see that as the light passes from air into block, it bends towards the normal because it slows down
5- when light reaches the boundary on the other side of the block, it’s passing into a less dense medium so speeds up and bends away from the normal
6- the emergent ray is travelling in the same direction as the incident ray-refracted to the normal and back by the same amount
7- measure the angle of incidence and angle of refraction made with the normal using protractor-calculate using snell’s law to find refractive index of material

Question 32

what do triangular prisms do to white light? and why?

Answer 32

desperse it because diff wavelengths refract by diff amounts so white light disperses into diff colours as it enters the prism because the boundaries aren’t parallel, so diff wavelengths don’t recombine- rainbow effect- violet is most bent as shortest wavelength

Question 33

refractive index=

Answer 33

speed of light in vacuum /speed of light in material= n=c/v

Question 34

what does refractive index tell you?

Answer 34

how fast light travels in that material

Question 35

why is the refractive index of glass high?

Answer 35

light slows down

Question 36

what’s the refractive index of air?

Answer 36

1

Question 37

what’s snell’s law?

Answer 37

n=sini/sinr

Question 38

what happens if you keep increasing the angle of incidence?

Answer 38

the angle of refraction gets closer to 90 degrees. eventually i reaches a critical angle C for which r=90. the light is refracted along the boundary

Question 39

what do you get above the critical angle?

Answer 39

total inernal reflection

Question 40

when i is less than Critical angle=

Answer 40

most light passes out but a little internally reflected

Question 41

when i is equal to Critical angle=

Answer 41

emerging ray goes along surface- quite a lot of internal reflection

Question 42

when i is greater than Critical angle=

Answer 42

no light comes out and all is internally reflected

Question 43

critical angle=

Answer 43

sinC= 1/n

Question 44

the higher the refractive index the lower the ?

Answer 44

critical angle

Question 45

how do optical fibres use total internal reflection?

Answer 45

made of plastic or glass and consist of a central core surrounded by cladding that has a lower refractive index. the core of the fibre is so narrow that light signals passing through it always hit the core-cladding boundary at angles higher than C- so light is always totally internally reflected. only stops working if fibre is bent tom sharply

Question 46

what are sound waves and what are they caused by?

Answer 46

they are longitudinal waves and caused by vibrating objects. the vibrations are passed through the surrounding medium as a series of compressions before it reaches your ear drum

Question 47

what happens to sound waves in denser medium?

Answer 47

they travel faster as they are caused by vibrating particles-so can’t travel through a vacuum are there are no particles

Question 48

what are sound waves reflected by?

Answer 48

hard surfaces

Question 49

how can you use an oscilloscope to measure the speed of sound?

Answer 49

1) attach a signal generator to a speaker at a specific frequency e.g. 1kHz.
2) start with both microphones next to speaker, then slowly move one away until the two waves are aligned on the display, but exactly one wavelength apart
3) measure the distance between the microphones to find the wavelength
4) use formula wave speed= frequency x wavelength to find the speed of sound waves passing through the air- f is whatever the signal generator is set to
5) should be around 340m/s

Question 50

How are waves diffracted?

Answer 50

They bend round edges and through gaps causing waves to spread out. This allows waves to travel round corners

Question 51

Wha makes the waves spread out more

Answer 51

The narrower the gap or the longer the wavelength

Question 52

What happens to the wave if the gap is much wider than the wavelength?

Answer 52

There’s little diffraction

Question 53

What happens to wave if gap is a bury wider than wavelength?

Answer 53

Diffraction only happens at edges

Question 54

What happens to the wave if the gap is the same as wavelength?

Answer 54

Maximum diffraction and perfect semi- circles

Question 55

The longer the wavelength of the wave, how much do they diffract?

Answer 55

The more they diffract

Question 56

how can you communicate any kind of information over long distance?

Answer 56

it needs to be converted into electrical signals

Question 57

what are the two signals?

Answer 57

analogue and digital

Question 58

how are these signals sent?

Answer 58

down telephone wires or carried on EM waves

Question 59

how do analogue signals work?

Answer 59

• it can take any value within a certain range.

- the amplitude and frequency of an analogue wave vary continuously

Question 60

how do digital signals work?

Answer 60

• can only take two values.

- called on/off or 1/0.

Question 61

what’s an example of digital signals being sent?

Answer 61

send data along optical fibres as short pulses of light

Question 62

what happens to both analogue and digital waves as they travel?

Answer 62

1- they weaken as they travel so need to be amplified along their route
2- they pick up interference or noise from electrical disturbances or other signals

Question 63

what happens when an analogue signal is amplified?

Answer 63

the noise is amplified too- so every time the signal loses quality

Question 64

what happens when a digital signal is amplified?

Answer 64

the noise is ignored so the signal remains high quality

Question 65

what happens when two or more waves of a similar frequency meet?

Answer 65

they can create one combined signal with a new amplitude- called interference
-happens when two radio stations transmit in similar frequencies

Question 66

what is easier because digital signals ignore noise?

Answer 66

it’s easier to transmit multiple signals using multiplexing

Question 67

what is multiplexing?

Answer 67

transmit multiple signals at the same time with just one cable or EM wave

Question 68

why can you use multiplexing with digital signals?

Answer 68

because the signals are easier to tell apart, so can transmit more info along the same chanel

Question 69

what is quantisation?

Answer 69

the process of ‘rounding’ multiple values to a smaller set. By doing this, you can pack more information into the same amount of space.

Question 70

how does quantisation work with digital signals?

Answer 70

as digital can only have two values, quantisation doesn’t lose much information

Question 71

how does quantisation work with analogue signals?

Answer 71

a lot of information is lost when a continuous range is rounded off

Question 72

how do vinyl records work?

Answer 72

• they are analogue- the needle on a record player goes up and down and side to side over the grooves in the disc forming an analogue wave which is converted to sound
• the grooves eventually wear away and the sound deteriorates- doesn’t happen with digital music

Question 73

what can happen to sound waves?

Answer 73

they can be diffracted through gaps and around obstacles- hear someone talking from around a corner as the sound waves will bend and spread out

Question 74

what’s an oscilloscope?

Answer 74

it displays sound waves

Question 75

how does an oscilloscope work?

Answer 75

1- a sound wave receiver, such as a microphone, can pick up sound waves travelling through the air
2- to display these waves, and measure their properties, you can plug the microphone into an oscilloscope. The microphone converts the sound waves to electrical signals
3- the oscilloscope is a device which can display the microphone signal as a trace on a screen
4- the appearance of the wave tells you whether the sound is loud or quiet and high or low-pitched
5- you can take detailed measurements to calculate the frequency of the sound by adjusting the settings on the display

Question 76

what increases with amplitude?

Answer 76

loudness

Question 77

what happens with a greater amplitude?

Answer 77

• the greater the amplitude of a wave or vibration, the more energy is carries- in sound it will be louder
• louder sound waves will have a trace with a larger amplitude on an oscilloscope

Question 78

the higher the frequency, the higher the?

Answer 78

pitch

Question 79

what is frequency?

Answer 79

the number of complete vibrations each second

Question 80

what are the units for frequency?

Answer 80

Hz- 1 vibration per second
kHz - 1000 Hz
MHz- 1 000 000 Hz

Question 81

the more complete cycles displayed on the oscilloscope screen then?

Answer 81

the higher the frequency

Question 82

if the source of sound vibrates with a high frequency then?

Answer 82

the sound is high-pitched

Question 83

if the source of sound vibrates with a low frequency then?

Answer 83

the sound is low-pitched

Question 84

how do you measure frequency on an oscilloscope?

Answer 84

• the horizontal axis on the display is time. the time between each division on the scale can be adjusted to get a clear, readable trace
  1) adjust the time division setting until the display shows at least 1 complete cycle
  2) read off the period- the time taken for one complete cycle e.g. 1 cycle crosses 20 divisions where each setting is 0.00001 s (from the setting) so period = 20 x 0.00001 = 0.0002 s
  3) frequency = 1/ time period= 1/-.0002 = 5000 Hz or 5 kHz