Polarisation is a property of transverse waves – waves whose oscillations are perpendicular to the direction of travel. Think of a rope being shaken up and down; the motion is sideways to the rope’s length. Light, radio waves and water surface waves are all transverse, so they can be polarised. Sound waves are longitudinal (they push and pull in the direction of travel) and cannot be polarised 🧪.
When a transverse wave travels, its oscillation can point in any direction within the plane perpendicular to the wave’s travel. A polariser (like a filter) only lets waves oscillating in one chosen direction pass through. The result is a wave that oscillates in a single direction – that’s a linearly polarised wave.
| Polarisation Type | Description |
|---|---|
| Linear | Electric field oscillates along one fixed direction. |
| Circular | Field rotates in a circle; magnitude constant. |
| Elliptical | General case; field traces an ellipse. |
The electric field of a linearly polarised wave can be written as:
\$E(z,t) = E_0 \cos(kz - \omega t)\,\hat{e}\$
where \$\hat{e}\$ is a unit vector giving the polarisation direction.
When two polarised waves pass through a second polariser, the transmitted intensity follows Malus’s Law:
\$I = I_0 \cos^2\theta\$
with \$\theta\$ the angle between the two polariser axes. 🔍
Remember:
|
Great job! You now understand that polarisation is a fascinating feature of transverse waves, and you’re ready to tackle exam questions on the topic. Keep practising with examples and remember the key points above. 🚀