The Photoelectric Effect
- The photoelectric effect is a phenomenon in which electrons are emitted from the surface of a metal upon the absorption of electromagnetic radiation
- Electrons removed from the surface of a metal in this manner are known as photoelectrons
- The photoelectric effect provides important evidence that light behaves as a particle i.e. it is quantised, or carried in discrete packets
- This is shown by the fact each electron can absorb only a single photon
Photoelectrons are emitted from the surface of metal when light shines onto it
Threshold Frequency
- Photoelectrons are emitted from the surface of a metal when light of sufficient energy shines on it
- The frequency of the photons required for the photoelectric effect to occur is called the threshold frequency
- The threshold frequency of a metal is defined as:
The minimum frequency of incident electromagnetic radiation required to remove a photoelectron from the surface of a metal
- Threshold frequency and wavelength are properties of a material and vary from metal to metal
Threshold frequencies and wavelengths for different metals
| Metal | Threshold Frequency f0 / Hz |
Threshold Wavelength λ0 / nm |
| sodium | 4.40 × 1014 | 682 |
| potassium | 5.56 × 1014 | 540 |
| zinc | 1.02 × 1015 | 294 |
| iron | 1.04 × 1015 | 289 |
| copper | 1.13 × 1015 | 266 |
| gold | 1.23 × 1015 | 244 |
| silver | 9.71 × 1015 | 30.9 |
Exam Tip
You are not required to memorise the threshold frequencies or wavelengths of different metals. These will be provided in the question if needed.
The Work Function
- The work function Φ, or threshold energy, of a material is defined as:
The minimum energy required to release a photoelectron from the surface of a metal
- Consider the electrons in a metal as trapped inside an ‘energy well’ where the energy between the surface and the top of the well is equal to the work function Φ
- One electron absorbs one photon
- Therefore, an electron can only escape from the surface of the metal if it absorbs a photon which has an energy equal to the work function Φ or higher
In the photoelectric effect, a single photon may cause a surface electron to be released if it has sufficient energy
- Different metals have different threshold frequencies and hence different work functions
- Using the well analogy:
- A more tightly bound electron requires more energy to reach the top of the well
- A less tightly bound electron requires less energy to reach the top of the well
- Alkali metals, such as sodium and potassium, have threshold frequencies in the visible light region
- This is because the attractive forces between the surface electrons and positive metal ions are relatively weak
- Transition metals, such as zinc and iron, have threshold frequencies in the ultraviolet region
- This is because the attractive forces between the surface electrons and positive metal ions are much stronger
Exam Tip
A useful analogy for threshold frequency is a fairground coconut shy:
- One person is throwing table tennis balls at the coconuts, and another person has a pistol
- No matter how many of the table tennis balls are thrown at the coconut it will still stay firmly in place – this represents the low frequency photons
- However, a single shot from the pistol will knock off the coconut immediately – this represents the high frequency photons
