2. EM Radiation and Quantum Phenomenon

Question 1

What happens if you shine a light of high enough frequency onto the surface of a metal?

Answer 1

Shining a light of high enough frequency onto the surface of a metal causes it to emit electrons.

Question 2

What is the frequency required for the photoelectric effect in most metals?

Answer 2

In the UV range.

Question 3

Describe how the photoelectric effect works.

Answer 3

• Free electrons on the surface absorb energy from photons.
• If an electron absorbs enough energy they will vibrate, the bonds holding it to the metal break and it is released.
• The emitted electrons are called photoelectrons.

Question 4

What 4 conclusions can be made from experiments on the photoelectric effect?

Answer 4

1. For a certain metal, no photoelectrons are emitted if the radiation is below a threshold frequency.
2. Photoelectrons have varying kinetic energies, up to a maximum. This maximum kinetic energy increases with radiation frequency.
3. Intensity of radiation is the amount of energy per second hitting an area of the metal. The maximum kinetic energy is not affected by intensity.
4. The number of photoelectrons per second is proportional to the intensity of radiation.

Question 5

What is the energy of an EM waves of a particular frequency proportional to? (Wave theory)

Answer 5

Energy carried should be proportional to the intensity of the beam.

(remember this is only for waves, not for the photoelectric effect)

Question 6

How is the energy of a wave distributed across it’s wavefront?

Answer 6

Spread evenly.

Question 7

What is the threshold frequency in the photoelectric effect?

Answer 7

The frequency of the radiation below which no photoelectrons are emitted.

Question 8

How does the frequency of the light affect the photoelectric effect?

Answer 8

The higher the frequency of the EM wave , the greater the maximum kinetic energy of the photoelectrons.

Question 9

How does the intensity of the light affect the photoelectric effect?

Answer 9

The higher the intensity, the more photoelectrons are emitted per second.

Question 10

Does the light intensity affect the maximum kinetic energy of photoelectrons?

Answer 10

No.

Question 11

What is light intensity?

Answer 11

The power (energy transferred per second) hitting a given area of a metal.

Question 12

Why can’t the photoelectric effect be explained by wave theory?

Answer 12

According to wave theory:
• For a certain frequency, energy is proportional to intensity.
• Therefore each free electron should get a bit of energy from each incoming wave.
• Gradually, each electron would gain enough energy to leave the metal. If an EM wave had low frequency it would take longer for electrons to gain enough energy but would eventually happen.
So:
• (Kinetic) energy transferred to electron should increase with intensity - It doesn’t!
• Electrons should be emitted eventually, regardless of frequency - But in reality, there is a threshold frequency!
- Kinetic energy depends on only frequency in the photoelectric effect - wave theory can’t explain this.

Question 13

For a certain frequency of light, the intensity is proportional to…

Answer 13

The energy carried.

Question 14

Why can wave theory not explain why the kinetic energy of a photoelectron in the photoelectric effect only increases with frequency (and not intensity)?

Answer 14

As light intensity increases, the energy transferred to each electron should increase also. This doesn’t happen.

Question 15

Why can wave theory not explain why the threshold frequency in the photoelectric effect?

Answer 15

The electrons should gradually gain energy and be emitted eventually, regardless of the radiation frequency. This doesn’t happen.

Question 16

Who suggested a photon model of light?

Answer 16

Einstein

Question 17

What is a photon?

Answer 17

A discrete packet of light.

Question 18

What is the equation for the energy of a photon?

Answer 18

E=hf

Where h = 6.63 x 10^-34

Question 19

In the photoelectric effect, how many electrons can each photon transfer its energy to?

Answer 19

Only one.

Question 20

How can the photoelectric effect be demonstrated with a zinc plate, an electroscope and a gold leaf?

Answer 20

Zinc plate is attached to the top of an electroscope (box with a piece of metal with a strip of gold leaf attached).

Zinc plate is negatively charged - this means the metal in the box is negatively charged.

The negatively charged metal repels the gold leaf, causing it to rise up.

UV light is then shone onto the zinc plate.

The energy of the light causes electrons to be lost from the zinc plate via the photoelectric effect.

As the zinc plate and metal lose their negative charge, the gold leaf is no longer repelled and so falls back down (towards the metal).

Question 21

How does a photocell work?

Answer 21

Question 22

How does the photon model of light explain the photoelectric effect?

Answer 22

• When EM hits the metal surface, it is bombarded by photons

* If one of these photons collides with a free electron, the electron will gain energy equal to hf.

Question 23

What is the work function of a metal?

Answer 23

The energy that must be supplied to an electron on the surface of a metal so that it can escape the metal as a photoelectron.

Question 24

What is the symbol for the work function?

Answer 24

Phi ϕ

Question 25

Is the work function of each metal the same?

Answer 25

No, it varies between metals.

Question 26

What happens when the energy gained by an electron is less than the work function?

Answer 26

No electron is emitted, but the electron vibrates and releases the energy as another photon. The metal heats up.

Question 27

What happens when the energy gained by an electron is more than the work function?

Answer 27

The electron is emitted from the metal.

Question 28

Give an equation for the threshold frequency.

Answer 28

f0 = ϕ / h

Question 29

Give an explanation for the range in energies of the photoelectrons emitted from a metal.

Answer 29

The ones deeper down in the metal lose more energy when exiting than the ones nearer the surface. (For example they might have to do work to get to the surface of the metal)

Question 30

What is the photoelectric equation?

Answer 30

hf = ϕ + Ek(max) where: Ek(max) = 1/2 x m x v(max)^2

Question 31

What is the reasoning for the equation: hf = ϕ + Ek(max)?

Answer 31

The minimun amount of energy an electron can loose is the work function energy. So the maximum kinetic energy is: Ek(max) = hf - ϕ This makes: hf = ϕ + Ek(max)

Question 32

What is the equation for the maximum kinetic energy of an electron in terms of mass and velocity?

Answer 32

Ek(max) = 1/2 x m x v(max)^2

Question 33

Why is the kinetic energy of a photoelectron independent of the intensity of light?

Answer 33

Each electron can absorb only one photon at a time.

Question 34

What is the definition of ionisation energy?

Answer 34

minimum energy needed to remove an electron from (an atom from) the ground state.

Question 35

What can the stopping potential be used for?

Answer 35

Measuring the maximum kinetic energy of photoelectrons.

Question 36

What is stopping potential?

Answer 36

The p.d. needed to stop the fastest moving photoelectrons emitted in the photoelectric effect.

Question 37

How does calculating the stopping potential work?

Answer 37

* Emitted photoelectrons are made to lose their energy by doing work against a potential difference. * The work done by the p.d. in stopping the fastest electrons is equal to the energy they were carrying.

Question 38

What equation is used in calculating the maximum kinetic energy of photoelectrons using their stopping potential?

Answer 38

Ek(max) = e x Vs Where: e = Charge on the electron (1.6 x 10^-19) Vs = Stopping potential

Question 39

What is the unit for Ek(max)?

Answer 39

Joules (J)

Question 40

Explain why the equation "Ek(max) = e x Vs" works.

Answer 40

* The work done by the potential difference is equal to p.d. x charge. * This work done is equal to the kinetic energy lost by the electron.

Question 41

Where in an atom can electrons exist?

Answer 41

Only in well-defined energy levels.

Question 42

What n value is the ground state given?

Answer 42

n = 1

Question 43

What is the lowest energy state of the atom called?

Answer 43

The ground state.

Question 44

What happens when an electron moves down an energy level?

Answer 44

A photon is emitted.

Question 45

Why can photons emitted due from an atom only have certain energies?

Answer 45

The electrons that cause the emission can only drop between energy levels, so the photons emitted can only take a certain value.

Question 46

Remember to revise energy level diagrams.

Answer 46

See revision guide pg 18 or pg 56 of textbook.

Question 47

Answer 47

Step 1) Draw it out Step 2) Find the energy of the photon, this is also the difference in energy between the two energy levels (ΔE) : E=hc/λ = hc/656x10^-9 = 3.03x10^-19 Joules Step 3) Convert into eV: 3.03x10^-19/1.60x10^-19 = 1.895007622 eV Step 4) IGNORE the negative sign - cross it out Step 5) We want to the initial energy level (the top one that the electron deexcites from) so use the equation : ΔE = Initial energy level - Final energy level. Remember we found ΔE and the final E was given in the question: 3.4 = 1.895007622 - initial energy level initial energy level = 1.895007622 - 3.4 initial energy = -1.50499 Step 6) Convert to Joules again: -1.50499 x 1.60x10^-19 = -2.4x10^-19 Joules

Question 48

Why will ΔE = Initial energy level - Final energy level?

Answer 48

Because it looses energy as it deexcites to final energy level.

Question 49

Why are electronvolts used instead of Joules when talking about photon energies?

Answer 49

The values are so small.

Question 50

What is an electronvolt?

Answer 50

The kinetic energy carried by an electron after it has been accelerated through a potential difference of 1 volt.

Question 51

How many Joules is one electronvolt?

Answer 51

1.6 x 10^-19

Question 52

How can the energy of an emitted photon be calculated by looking at the drop of the the electron?

Answer 52

It is the difference in energies between the two levels.

Question 53

What is excitation?

Answer 53

When an electron absorbs a photon of the exact energy and moves to a higher energy level.

Question 54

When can excitation happen?

Answer 54

When the photon aborbed by the electron has energy equal to the difference between the two energy levels that the electrons moves between.

Question 55

What is ionisation?

Answer 55

When an electron gains enough energy to escape from an atom.

Question 56

What does the energy of each energy level refer to?

Answer 56

The amount of energy required to remove an electron at that energy from the atom.

Question 57

What is the energy carried by a photon (emitted after a transition) equal to?

Answer 57

The difference in energies between the two levels of the transition.

Question 58

What equation shows the difference in two energy levels?

Answer 58

Question 59

Answer 59

Question 60

What is the ionisation energy of an atom?

Answer 60

The amount of energy required to completely remove an electron from an atom from the ground state (n=1).

Question 61

What is the ionisation energy of an unexcited hydrogen atom as seen from the diagram:

Answer 61

13.6 eV

Question 62

What is the main component that fluorescent tubes contain?

Answer 62

Mercury vapour at low pressure.

Question 63

How does a fluorescent tube work?

Answer 63

• A high voltage is applied across a tube filled with mercury vapour, which accelerates free electrons • Some of the mercury atoms are ionised by collisions, producing more free electrons • Other mercury atoms are excited by collisions • When these excited electrons return to their ground states, they lose energy as photons in the UV range are emitted. The photons emitted have a range of energies and wavelengths corresponding to the different transitions of electrons. • The phosphorus coating on the inside of the tube absorbs these, exciting the electrons to much higher energy levels. Thr electrons cascade down the energy levels and loses energy by emitting lower energy visible photons.

Question 64

What coating is placed on the inside of fluorescent tubes?

Answer 64

Phosphorus

Question 65

How does the coating on the inside of a fluorescent tube work?

Answer 65

* Atoms in the coating are excited by the UV photons | * When these de-excite, lower energy light photons are emitted.

Question 66

What is a line emission spectrum?

Answer 66

A series of non-continuous colours against a black background, where each line corresponds to a particular wavelength of light emitted by a source.

Question 67

What can be used to create a line spectrum?

Answer 67

* Prism | * Diffraction grating

Question 68

What do line emission spectra provide evidence for?

Answer 68

Question 69

What are the two types of light spectra?

Answer 69

* Line spectrum | * Continuous spectrum

Question 70

What is a continuous spectrum?

Answer 70

A series of unbroken colours, where light of different wavelengths merges into each other without gaps.

Question 71

A spectrum of white light is...

Answer 71

...continuous.

Question 72

What can be used to create a continuous spectrum?

Answer 72

• Prism

Question 73

Why do hot things emit a continuous spectra?

Answer 73

Hot things emit a continuous spectrum in the visible and infrared. All wavelengths are allowed because the electrons are not confined to energy levels in the object producing the continuous spectrum. The electrons are not bound to atoms and are free.

Question 74

What is produced when white light is shone through a cool gas?

Answer 74

Line absorption spectrum

Question 75

What happens when white light is shone through a cool gas?

Answer 75

* At low temperatures, most atoms in the gas are at ground state * The electrons can only absorb photons that correspond to differences in energies of energy levels * Therefore, photons of specific wavelengths are absorbed and are missing from the spectrum when it comes out the other side of the gas.

Question 76

What happens when the absorption and emission spectra of a particular gas are compared?

Answer 76

You see a continuous spectra of lines in it corresponding to the absorbed wavelength. The black lines in the absorption spectrum and bright lines in the emission spectrum match up.

Question 77

What ideas show light as a wave?

Answer 77

* Interference | * Diffraction

Question 78

What happens when a beam of light passes through a slit?

Answer 78

It spreads out - diffracts

Question 79

Diffraction can only be explained by using...

Answer 79

Waves.

Question 80

If light behaved as particles, how would it pass through a slit?

Answer 80

light particles would either not get through (if they were too big) or just pass straight through and the beam would be unchanged

Question 81

What ideas show light as a particle-like photon?

Answer 81

• Photoelectric effect experiments.

Question 82

How does the photoelectric effect show that light could be a particle?

Answer 82

If a photon of light is a discrete bundle of energy, then it can interact with an electron in a one to one way.

Question 83

What did the results from the photoelectric effect prove?

Answer 83

That light behaves as a wave and particle = wave-particle duality

Question 84

Who came up with the wave-particle duality theory?

Answer 84

de Broglie

Question 85

What hypothesis did de Broglie come up with?

Answer 85

If wave-like light showed particle properties, particles like electrons should be expected to show wave-like properties.

Question 86

What is the de Broglie equation and what is it used for?

Answer 86

* It is used to calculate the wavelength of a moving particle. * It links a wave property (wavelength) with a moving particle property (momentum).

Question 87

What is the equation for the wavelength of a moving particle?

Answer 87

λ = h / mv | Where: mv is the momentum (equal to mass x velocity).

Question 88

Answer 88

(i) E = hf. This is the energy the electrons will have. This is same as the energy of the photons. The energy required to remove the electron varies (hence kinetic energy of electrons will vary). (ii) Work function is the minimum energy needed to release an electron.. Below a certain frequency, energy of the photon is less than the work function (E=hf).

Question 89

How were scientists eventually convinced by de Broglie about wave-particle duality?

Answer 89

Peer reviewed before he published it. Tested through experiments like electron diffraction = provided evidence to be validated by scientists.

Question 90

State an idea that shows the wave nature of electrons.

Answer 90

• Electron diffraction

Question 91

How can electron diffraction be observed?

Answer 91

Electron diffraction tube: Electrons are accelerated to high velocities in a vacuum and then passed through graphite crystal. They diffract through the spaces between the atoms of the crystal. They produce a pattern of rings. This provides evidence to show that light has wave properties.

Question 92

How does the diffraction pattern of electrons change if the wavelength is increased?

Answer 92

The rings are larger and more spaced out.

Question 93

Explain how and why increasing the speed of electrons in electron diffraction changes the diffraction pattern.

Answer 93

Increased speed of electrons -> de Broglie wavelength is smaller -> Less diffraction -> Smaller rings

Question 94

In electron diffraction, how can the speed of the electrons be changed?

Answer 94

Varying the potential difference between the filament and the metal plate.

Question 95

The wavelength of electrons accelerated in a vacuum tube is about the same as...

Answer 95

...electromagentic waves in the X-ray part of the spectrum.

Question 96

When do you only get diffraction?

Answer 96

If a particle interacts with an object of about the same size as it's de Broglie wavelength.

Question 97

How does increasing the mass of particles in diffraction affect the diffraction pattern and why?

Answer 97

* The greater mass reduces the de Broglie wavelength, so less diffraction happens. * This gives smaller, tighter rings. This is because higher mass means higher momentum = shorter de Broglie wavelength.

Question 98

Do particles always show wave properties? Why?

Answer 98

No, diffraction only happens if the particle interacts with something of a similar size to its de Broglie wavelength. For example, a tennis ball would have a tiny wavelength and could interact with nothing.

Question 99

Explain how the idea of wave-particles duality was developed.

Answer 99

* De Broglie hypothesised wave-particle duality * Other scientists had to evaluate the theory (peer review) before he published it * Then it was tested with experiments * Once there was enough evidence, the theory was validated

Question 100

Answer 100

hf is the same energy from photons. energy required to remove the electron varies (hence kinetic energy of electrons will vary).

Question 101

What does diffraction effect on an image?

Answer 101

blur

Question 102

If you want less blur on an image what should you consider?

Answer 102

Shorter wavelength to resolve tiny detail

Question 103

How can you have less diffraction in microscopes?

Answer 103

Use electron waves - light blurs out details more than electron waves. Electron microscope can resolve finer details -e.g. they can see strands of DNA.