Topic 5 - Waves / Particle Nature of Light

Question 1

longitudinal waves

Answer 1

a type pf wave in which the particles oscillate parallel to the direction of the wave

Question 2

wavelength

Answer 2

the distance between two matching points in neighbouring waves, measured in metres (m)

Question 3

amplitude

Answer 3

the maximum displacement a point moves from its centre of oscillation, measure in metres (m)

Question 4

The larger the amplitude…

Answer 4

the greater the energy

Question 5

period

Answer 5

the time taken for a point on a wave to move through one complete oscillation, measures in seconds (s)

Question 6

frequency

Answer 6

the number of oscillations per second, measured in Hertz (Hz)
OR
the number of waves that pass a point in one second, measured in Hertz (Hz)

Question 7

freqeuncy =

Answer 7

1/time period

Question 8

describe electronmagnetic waves

Answer 8

transverse waves made up of electric and magnetic fields which transfer energy from one place to another. All of the waves travel the same speed in a vacuum.

Question 9

higher frequency means…

Answer 9

more energy

Question 10

what is the order of the electronmagnetic spectrum?

Answer 10

radio, micro, IR, visible, UV, x-ray, Gamma

Question 11

what is the wavelength of a radio wave?

Answer 11

10^3 - 10^1 m

Question 12

what is the wavelength of a microwave?

Answer 12

10^-2 m

Question 13

what is the wavelength of a Infra-red wave?

Answer 13

10^-5 m

Question 14

what is the wavelength of a visible light wave?

Answer 14

10^-7 m

Question 15

what is the wavelength of a ultra violet wave?

Answer 15

10^-8 m

Question 16

what is the wavelength of a x-ray wave?

Answer 16

10^-10 m

Question 17

what is the wavelength of a gamma ray?

Answer 17

10^-12 m (+)

Question 18

diffraction

Answer 18

is the spreading out of a wave as it goes past an obstacle or through a gap

Question 19

What is Huygens principal?

Answer 19

a model where each point on a wave front may be regarded as a source of waves expanding from that point.
it allowed a visualisation of how light could penetrate into geometric shadow in a way that particles could not

Question 20

What is a diffraction grating?

Answer 20

an optical component with a periodic structure that splits and diffracts light into several beams travelling in different directions.

Question 21

constructive interfence

Answer 21

is known as in phase, where a trough and trough meet or a peak and a peak meet. the waves have the same frequency and wavelength but double(the addition of the two waves) the amplitude.

Question 22

What is superposition?

Answer 22

when the wave amplitudes are added

Question 23

destructive interference

Answer 23

is known as out of phase, where a trough of one wave meets a peak of another wave the waves must have the phase difference of 180 degrees. the waves cancel each other out.

Question 24

degrees to radians conversion

Answer 24

radians = (degrees * pi)/180

Question 25

radians to degrees conversion

Answer 25

degrees = (radians *180) / pi

Question 26

For two waves of light to be coherent the waves must

Answer 26

originate from one source

Question 27

how does a additional converging lens effect the eye

Answer 27

decreases the image distance as the lens adds more power

Question 28

virtual image

Answer 28

cannot be projected onto a screen

Question 29

unit of viscosity

Answer 29

PaS

Question 30

why does intensity decrease over distance

Answer 30

the area the wave is spread out over is larger so the intensity is lower (interference can also effect the intensity)

Question 31

wave speed

Answer 31

the speed the wave travels. v = fλ

Question 32

wave equation

Answer 32

v = fλ

Question 33

wave

Answer 33

something that transfers energy from one point to another

Question 34

describe a longitudinal wave

Answer 34

particles in metal vibrate along direction of propagation making compressions and rarefractions

Question 35

frequency time period equation

Answer 35

f = 1/T

Question 36

dispersion

Answer 36

when waves separate out due to a wave travelling through a different medium (different wavelengths travel at different speeds)

Question 37

intensity equation

Answer 37

I = P/A

Question 38

intensity distance relationship

Answer 38

inverse square law

Question 39

intensity, I

Answer 39

the rate of flow of energy per unit area perpendicular to the direction of travel of the wave

Question 40

speed of sound in air

Answer 40

340 m/s

Question 41

speed of light in a vacuum

Answer 41

3e8m

Question 42

phase difference

Answer 42

how much one wave is in front or behind another wave

Question 43

Transverse wave

Answer 43

a type of wave in which particles oscillate perpendicular to the direction of energy transfer in the wave

Question 44

rarefraction

Answer 44

oscillations are far apart

Question 45

compression

Answer 45

oscillations are close together

Question 46

how does a graph show transverse waves

Answer 46

displacement distance graph

displacement shows amplitude

Question 47

How does a graph show longitudinal waves

Answer 47

displacement time graph

Question 48

what type of wave an EM wave

Answer 48

transverse waves

Question 49

wavefront

Answer 49

the leading edge of one complete wave

Question 50

coherence

Answer 50

same frequency + unchanging phase difference

Question 51

superposition

Answer 51

The resultant displacement can be found by adding the two displacements together from interfering waves

Question 52

when does superposition occur?

Answer 52

for all waves, even if they’re no coherent.

Question 53

superposition of coherent waves

Answer 53

provides a constant patter of interference

Question 54

path difference

Answer 54

the difference in distance traveled by the two waves from their respective sources to a given point on the pattern

Question 55

difference between phase difference and path difference

Answer 55

phase difference is worked out by path difference. There could be zero phase difference but still have a path difference.

Question 56

What is the structure of an EM wave?

Answer 56

electric and magnetic fields which oscillate in phase and are perpendicular to each other

Question 57

progressive wave characteristics

Answer 57

• transfers energy
• each point will reach the same amplitude
• each particle oscillates over the same path but there is a phase lag between each particle

Question 58

standing/stationary wave charateristics

Answer 58

• stores energy
• amplitude varies
• between two nodes all the particles oscillate in phase; on either side of a node there are outp of phase

Question 59

how are stationary waves formed in a string?

Answer 59

the wave reflects back from a terminator and interferes with itself

Question 60

resonant frequencies

Answer 60

a natural frequency of vibration determined by the physical parameters of the vibrating object.

Question 61

harmonics

Answer 61

a wave where its frequency is a multiple of the material natural frequency resulting in a standing wave

Question 62

Where are nodes on a standing wave in a string

Answer 62

at the end of the string (+in between depending on the harmonic)

Question 63

mass per unit length

Answer 63

mass of an object divided by it length, the thickness of string effects this

Question 64

how to calculate wave speed of a standing wave on a string

Answer 64

V = √(T/μ)

where μ is the mass per unit length

Question 65

how is a standing wave formed inside a closed pipe?

Answer 65

blowing an air column down a closed pipe results in it being reflected back up. The two waves superpose to form a stationary longitudinal wave.

Question 66

How is stationary waves in a pipe drawn in a diagram?

Answer 66

drawn as a displacement distance graph, so it appears as a transverse wave

Question 67

where is a node formed in a closed pipe standing wave

Answer 67

at the closed end

Question 68

why is a node formed at the closed end of a pipe

Answer 68

the air cannot oscillate freely

Question 69

Where is an antinode formed in a closed pipe

Answer 69

at the open end

Question 70

whats different about closed pipe harmonics

Answer 70

it can only form odd harmonics

Question 71

Where is a anti node formed in an open pipe

Answer 71

at both ends (because they’re open)

Question 72

wave diagram

Answer 72

shows the wave fronts (straight lines perpendicular to direction of travel)

Question 73

ray diagram

Answer 73

show a single ray and the direction and action of a wave

Question 74

reflection

Answer 74

the change in direction of a wavefront at an interface between two different media so that the wavefront returns into the medium from which it originated

Question 75

laws of reflections (2)

Answer 75

• when light is reflected, the incident ray, the reflected ray and the normal all lie inside the same plane
• the angle i between the incident ray and the normal is the same as the angle r between the reflected ray and the normal

Question 76

angles in reflection

Answer 76

the angle i between the incident ray and the normal is the same as the angle r between the reflected ray and the normal

Question 77

refraction

Answer 77

the change in direction of wave propagation due to it moving through a different medium

Question 78

why does refraction occur

Answer 78

waves travel at different speeds in different mediums.

Question 79

less dense -> more dense

how does light bend

Answer 79

towards the normal

Question 80

snells law

Answer 80

n = sini/sinr = c/v

Question 81

refractive index letter

Answer 81

n

Question 82

absolute refractive index

Answer 82

a ratio of the speed of light in a vacuum to the speed of light in a given medium

Question 83

1n2 =

calculating the refractive index between two materials

Answer 83

n2/n1

where n2 and n1 are the absolute refractive indexes of each material

Question 84

critical angle

Answer 84

the largest angle at which refractuib out of a denser medium is possible

Question 85

refraction between two mediums equation

Answer 85

n1sin θ1= n2 sin θ2

Question 86

how do you calculate the critical angle?

Answer 86

by making θ2 90 degrees in the equation:
n1sin θ1= n2 sin θ2

n = 1/sinC

Question 87

absolute refractive index of air

Answer 87

1

Question 88

absolute refractive index of water (use to check calculations)

Answer 88

1.33

Question 89

total internal reflection

Answer 89

the complete reflection of a wave where the angle of incidence exceeds the critical angle

Question 90

if i is less than the critical angle then

Answer 90

refraction

Question 91

if i = critical angle =>

Answer 91

particial TIR (multiple rays)

Question 92

if i>critical angle =>

Answer 92

TIR

Question 93

how to measure the refractive index of a solid material

Answer 93

use a glass block to shine light through and trace the path

Question 94

focal length

Answer 94

the distance between the optical centre and the principle focus

Question 95

diverging lens

Answer 95

a concave lens

Question 96

converging lens

Answer 96

a bulging lens

Question 97

convex lens

Answer 97

converging

Question 98

concave lens

Answer 98

diverging

Question 99

ray bending in a converging lens

Answer 99

going in: bends towards the normal

going out: bends away from the normal

Question 100

if the object is between the focal length and a converging lens then the image is

Answer 100

• magnified
• upright
• virtual image

Question 101

if the object is beyond the focal length of a converging lens then the image is

Answer 101

• magnified
• inverted
• real image

Question 102

virtual principal focus

Answer 102

is you trace back the diverged rays to a single point

Question 103

power of a diverging lens

Answer 103

always negative

Question 104

What does diverging lens do to the image

Answer 104

• diminished
• upright
• virtual image

Question 105

what does the focal length depend on

Answer 105

the curvature of the surface and the material used

Question 106

the more powerful the lens the…

Answer 106

shorter the focal length

Question 107

power of a lens equation

Answer 107

P = 1/f

Question 108

lens equation

Answer 108

1/f = 1/u + 1/v
distances to real objects and images are postive
distances to virtual images are negative
focal length of converging is positive, focal length of diverging is negative

Question 109

magnification equation

Answer 109

magnification = image distance/ object distance

Question 110

real image

Answer 110

an image that can be projected onto a screen

Question 111

virtual image

Answer 111

an image that can’t be projected onto a screen (appears to come from behind the lens)

Question 112

combing lens powers

Answer 112

P = P1 + P2 + P3…

for thin lenses

Question 113

ray diagram for converging lens (object beyond focal length)

Answer 113

1. draw a horizontal line from the top of the object to the y axis then down through the focal point on the opposite side
2. draw a line directly through the centre of the axes from the top of the object
3. draw a line through the focal point on the same side of the lens, when it hits the y axis go horizontally across. Where all three lines cross is the top of the image.

Question 114

ray diagram for converging lens (object between focal point and lens)

Answer 114

1. draw a horizontal line from the top of the object to the y axis then down through the focal point on the opposite side
2. draw a line directly through the centre of the axes from the top of the object
3. from the two sloped lines dot each one back. Where they cross is the top of the object

Question 115

ray diagram for diverging lens

Answer 115

1. draw a horizontal line from the top of the object to the y axis then align the rule with the focal point on the same side of the lens and draw a line up from the point of the y axis
2. draw a line directly through the centre of the axes from the top of the object
3. trace back the upward sloped line, where it crosses the downward diagonal is where the top of the image is

Question 116

not polarised

Answer 116

wave oscillates in all directions

Question 117

plane polarsied

Answer 117

wave oscillates in one plane only

Question 118

plane polarised examples

Answer 118

scattered/reflected light, microwave and radiowave sources

Question 119

polarising longitudinal waves

Answer 119

can’t be done

Question 120

crosses polarised

Answer 120

when filters are perpendicular to each other so no light can get through

Question 121

diffraction

Answer 121

the spreading out of a wave as it goes past an obstacle or through a gap

Question 122

When a wave passes through a gap that is a similar size to their wave length…

Answer 122

there is a lot of diffraction

Question 123

monochromatic

Answer 123

only one wavelength

Question 124

interference pattern

Answer 124

a series of maximum and minimum points that can be seen on a screen from interfering coherent waves

Question 125

nλ =

Answer 125

= dsinθ

Question 126

d =

Answer 126

slit spacing

Question 127

how to calculate d from lines per m

Answer 127

n = 1/(lines per m)

Question 128

What did planck work on?

Answer 128

• He looked at black body radiation
• He theorised that radiation was emitted in discrete packets of energy
• he found there was a link between energy and frequency

Question 129

What is a Quanta?

Answer 129

discrete packets of energy

Question 130

plancks equation

Answer 130

E=hf

Question 131

h value

Answer 131

6.633e-34

Question 132

What did einstein theorise?

Answer 132

That concentrated packets of energy had particle like properties and were called photons

Question 133

photon

Answer 133

concentrated discrete packets of energy which have particle like properties

Question 134

What is the EM spectrum from a particle point of view?

Answer 134

many photons with different levels of energy

Question 135

How much do photons weigh?

Answer 135

weightless

Question 136

how can photons travel at the speed of light?

Answer 136

because theyre weightless

Question 137

what letter represents the speed of light?

Answer 137

c

Question 138

how is the equation E = hc/ lambda formed?

Answer 138

combining E=hf and c=fλ

Question 139

Electron volt

Answer 139

One electronvolt is the energy gained by an electron when it is accelerated through a p.d. of 1v (W= QV)

Question 140

how to convert joules to eV

Answer 140

divide by 1.6x10^-19

Question 141

how to convert eV to Joules

Answer 141

multiply by 1.6x10^-19

Question 142

how to find plancks constant?

Answer 142

• set up a potential divider circuit with a paralell section with different coloured LEDs, an ammeter and a voltmeter
• measure the voltage and record the wavelength (read from packet)
• plot a graph of v agaisnt 1/λ
• the gradient equals Vλ
• substitute E = eV into E =hc/λ input gradint value and rearrange to get h

Question 143

Who worked out the photoelectric effect?

Answer 143

Einstein

Question 144

What is the photoelectric effect?

Answer 144

the emission of electrons from the surface of, generally, a metal in response to incident light.

Question 145

What shows the photoelectric effect?

Answer 145

when a charge is given to an electroscope they repel each other so the gold leaf will lift and move away from the metal pole.

Question 146

How can the charge of an electroscope be found?

Answer 146

the angle the gold leaf lifts too

Question 147

why does the wave model no backup the photoelectric effect?

Answer 147

all the frequencies should combine energy to liberate the electrons

Question 148

how many photons can liberate a single electron?

Answer 148

1

Question 149

if wavelength increases…

Answer 149

frequency decreases therefore electrons have less kinetic energy and eventually none are liberated

Question 150

if wavelength decrease

Answer 150

frequency increases therefore electrons have more kinetic energy

Question 151

if intensity increases

Answer 151

more electrons are increased but with the same kinetic energy. if it is below the threshold frequency intensity has NO effect

Question 152

electrons are trapped inside __________ and in order to escape it has to _________

Answer 152

energy wells

absorb enough energy

Question 153

How does the material effect the energy well?

Answer 153

different sizes therefore different amounts of energy are needed to liberate the electrons

Question 154

work function

Answer 154

the amount of energy needed for the electrons to escape their energy well

Question 155

which formula works out the work function

Answer 155

hf = Φ + E.K. max

Question 156

if the electron is given just enough energy to release from the energy well its kinetic energy equals 0 therefore….

Answer 156

threshold frequency can be found by Φ/h

Question 157

it doesn’t matter how many IR photons land on the metal… if

Answer 157

all of them are below the freshold frequency no single electron will be liberated

Question 158

photoelectron

Answer 158

a liberated electron

Question 159

intensity is proportional to

Answer 159

rate of emmision of photoelectrons

Question 160

Broglie said that for

Answer 160

any particle that had momentum it also has wavelength λ = h/p

Question 161

relativistic mass

Answer 161

as a particle gets closer to the speed of light the mass tends to increase due to relativistic effects

Question 162

The intensity of a wave at a point represents

Answer 162

the probability of a wave being there

Question 163

the electrons have _____ different energy levels by its energy is _______

Answer 163

infinite

finite

Question 164

how do you work out the energy changes of an atom?

Answer 164

calculate the frequency and wavelength needed to give the energy to move up levels and equally how much is emitted when it falls back down levels

Question 165

emission spectra

Answer 165

shows the certain wavelengths of photons which are given off by an element after it is excited and the electrons drop back down to there original energy levels ad emit energy

Question 166

absorption spectra

Answer 166

where certain frequencies of light are missing because they’re being absorbed by that element

Question 167

Threshold frequency

Answer 167

the lowest frequency of light at which electrons are still released from a surface

Question 168

what experiment determines the work function of different materials and the value of h?

Answer 168

stopping voltage experiment

Question 169

What does the graph from the stopping voltage experiment show?

Answer 169

gradient = h
F0 (x intercept) = threshold frequency
y intercept = work function

Question 170

What does the y intercept from the stopping voltage experiment show?

Answer 170

the voltage needed to stop an electron being liberated by light of 0 frequency and so 0 energy (the work function)

Question 171

What axises are plotted from the stopping voltage experiment?

Answer 171

y = stopping voltage 
x = frequency

Question 172

if the p.d. in a stopping voltage experiment is increased what happens?

Answer 172

electrons are accelerated faster as they move in the same direction as the current

Question 173

if the pd. in a stopping voltage experiment is decreased what happens?

Answer 173

the battery is more effective than the photoelctric effect therefore the electrons are slowed and start to move backwards.

Question 174

what is stopping voltage?

Answer 174

the voltage at which the battery becomes more powerful than the photoelectric effect and the electrons are slowed

Question 175

Why are electrons only emitted about a threshold frequency?

Answer 175

Photon energy is proportional to frequency therefore photon energy must be greater than the work function to liberate an electron. All the energy must come from a single electron.

Question 176

Line spectra

Answer 176

Specific frequencies/wavelengths show the absorbtion/ emmision lines within a narrow line of wavelengths

Question 177

How do line spectra provide evidence for the existence of energy levels in atoms

Answer 177

Photons associated with particular energies show electron transitions up and down the discrete energy levels

Question 178

wave model features

Answer 178

• diffraction
• refraction
• reflection
• have a frequency
• interfere with each other
• pass through each other

Question 179

photon model features (features of particles)

Answer 179

• have mass
• reflect
• experiences forces between each other
• have volume
• can have charge
• have momentum
• have density

Question 180

The shorter the pulse…

Answer 180

the shorter the distance that can be measured

Question 181

why does the photon model work for photoelectric effect

Answer 181

• The energy of one photon is used to liberate one electron meaning the threshold frequency must be high enough
• The energy is proportional to the frequency and any energy greater than the work function is transferred t the electron as kinetic energy

Question 182

Why does the wave model not work for the photoelectric effect

Answer 182

• frequency would build up to high enough to liberate and electron
• K.E. would depend on the intensity of the light

Question 183

long wavelength photon means…

Answer 183

less energy levels moved up

Question 184

high frequency photon means…

Answer 184

the more energy levels it jumps up

Question 185

how is a photon emitted

Answer 185

electrons don’t remain in an excited state so they de-excite and drop down to the ground state and emit energy in the form of a photon

Question 186

how can electrons be excited?

Answer 186

• if a photon is absorbed

- if electrons are hit be other electrons

Question 187

energy delivered by photon (hf) =

Answer 187

difference between the energy levels

Question 188

ground state

Answer 188

the lowest energy level where electrons are usually found

Question 189

Why are only certain frequencies absorbed by atoms?

Answer 189

electrons can only exist in discrete energy levels

Question 190

Kinetic energy gained by accelerating electron through a potential difference =

Answer 190

eV

Question 191

the amount of diffraction that a wave undergoes depends on the

Answer 191

amplitude of the incident wave and the size of the opening

Question 192

experiment to show that electrons behave as a wave

Answer 192

direct the electrons through a crystal. if the size of the crystal atom is similar to the wavelength of the electron it diffracts (a wave property)

Question 193

why is diffraction move obvious with sound than light

Answer 193

sound has a longer wavelength so it occurs more at our scale

Question 194

intensity of light through two Polaroids is greatest when

Answer 194

the Polaroids are parallel

Question 195

hf

Answer 195

energy of a photon

Question 196

Ф

Answer 196

The energy required from a single photon to release an electron from its energy well (work function)

Question 197

kinetic energy of photoelectrons depends on…

Answer 197

the frequency of the incident photon

Question 198

more intense light means….

Answer 198

more photoelectrons released (IF FREQUENCY OVER THRESHOLD FREQUENCY)

Question 199

what does the number of maxima correspond to?

Answer 199

the highest integer value of d/λ is the number of maxima on one side of the central order (not including the central order)

Question 200

Why are certain frequencies missing from an absorption spectrum?

Answer 200

• electrons get excited by absorbing photons
• electrons have fixed energy levels. only certain transitions possible, so only certain photon energies absorbed so some frequencies missing
• the set of frequencies absorbed depends on the element

Question 201

energy of photon absorbed =

Answer 201

difference in energy levels

Question 202

range of visible light wavelengths

Answer 202

400nm - 700nm

Question 203

how to get the first order maxima closer together?

Answer 203

increase the frequency of the laser

Question 204

as speed decreases…

Answer 204

wavelength decreases

Question 205

wave property which only applies to transverse waves?

Answer 205

polarisation

Question 206

not polarised

Answer 206

oscillates in all the planes perpendicular to the direction of travel

Question 207

standing wave

Answer 207

a series of nodes and antinodes formed for interfering coherent waves

Question 208

out of phase value in radians

Answer 208

pi

Question 209

in phase value

Answer 209

0, 2 pi

Question 210

fundamental frequency

Answer 210

lowest frequency of a standing wave that can be set

Question 211

frequency of ultrasound

Answer 211

20 000 Hz

Question 212

image from a lens where the object is beyond 2x the focal length

Answer 212

inverted
diminished
real

Question 213

object on focal point convex lens

Answer 213

ray are parallel, no image will be formed

Question 214

long sight

Answer 214

the power is too weak so it doesn’t converge on the retina

Question 215

short sight

Answer 215

to powerful, the image converges before the retina

Question 216

milikans experiment

Answer 216

• they let the small drops of oil fall between the two plates
• by adjusting the pd between the plates the forces were balanced on the drop
• mg = vQ/d to work out Q
• to find m they needed to measure the radius, they let it move at terminal velocity and used forces to find r

Question 217

milikans experiment conclusion

Answer 217

measured the charge of an oil drop to be always a multiple of 1.6e-19 so he deduced the charge of an electron is 1.6e-19 C

Question 218

milikans experiment set up

Answer 218

electric field
atomiser to spray oil drops into the electric field
a microscope to view the oil drops

Question 219

how did the find out r in milikans experiment

Answer 219

• let it fall at terminal velocity and then used forces

- 6πνrv = mg = 4/3ρgπr^3

Question 220

frequency from number of oscillations in a given time

Answer 220

f = number of oscillations / time

Question 221

line spectra

Answer 221

specific narrow band of frequencies or wavelengths that an element has absorbed/emitted

Question 222

What does firing electrons through a screen show about their nature

Answer 222

• Electrons spread out and form an interference pattern

- Electrons must behave as waves (their wavelength is a similar size to the spacing)

Question 223

What does vertically polarised mean?

Answer 223

light only oscillates in the vertical plane perpendicular to the direction of travel

Question 224

Why can two oppositely polarised sources not interfere

Answer 224

the oscillate perpendicular to each other so the opposite/ same components cannot undergo superposition

Question 225

explain how refraction is caused (2 parts)

Answer 225

• materials are different densities

- light changes direction and appears to come from another point

Question 226

critical angle

Answer 226

the angle of incidence for light travelling from a denser medium has angle of refraction of 90