Polarization Experiment for Schools, Teachers, and Students
Malus’ Law describes the intensity of light transmitted through a polarizer-analyzer system. It states that the intensity of polarized light after passing through a second polarizer (analyzer) depends on the angle between the axes of the polarizer and analyzer.
Theory:
- The mathematical expression for Malus’ Law is:
I = I₀ cos²θ
where:- I is the transmitted intensity
- I₀ is the initial intensity of the light
- θ is the angle between the transmission axes of the polarizer and analyzer
- The amplitude of the light wave also changes when passing through a polarizer. The relationship between the transmitted amplitude A and the initial amplitude A₀ is given by:
A = A₀ cosθ
Since intensity I is proportional to the square of the amplitude, this leads to the cos²θ dependence for intensity. For unpolarized light passing through a polarizer, the amplitude becomes:
A = A₀ / √2 - Malus’ Law applies to light that is initially polarized. For unpolarized light passing through a polarizer, the transmitted intensity is half the initial intensity:
I = I₀ / 2
This happens because a polarizer transmits only the component of light aligned with its axis. - If the analyzer’s axis is parallel to the polarizer’s axis (θ = 0°), maximum intensity is transmitted:
I = I₀ - If the analyzer’s axis is perpendicular to the polarizer’s axis (θ = 90°), no light is transmitted:
I = 0
Real-Life Uses:
- Polarized sunglasses reduce glare by blocking polarized light reflected from surfaces like water or roads.
- Liquid crystal displays (LCDs) utilize polarizers to control light transmission for image formation.
- Optical communication systems use polarizers for reducing signal interference.
- Stress analysis in materials employs polarized light to visualize stress patterns.
Observations:
- Increasing θ reduces the transmitted intensity following a cos²θ dependence.
- Maximum transmission occurs at θ = 0°, and minimum at θ = 90°.
- Introducing a third polarizer between two crossed polarizers (analyzer at 90° to the polarizer) can transmit some light, depending on its orientation.
- Unpolarized light becomes partially polarized when passing through a single polarizer.
- The amplitude of light decreases linearly with cosθ, while intensity decreases with cos²θ.
- For unpolarized light passing through a polarizer, the amplitude becomes A₀ / √2.
Summary Table:
| Type of Light | Intensity Formula | Amplitude Formula |
|---|---|---|
| Polarized Light | I = I₀ cos²θ | A = A₀ cosθ |
| Unpolarized Light (After Polarizer) | I = I₀ / 2 | A = A₀ / √2 |
