A beam of unpolarized light of intensity I₀ passes through a series of ideal polarizing filters with their polarizing axes turned to various angles as shown in Fig. E33.27. If we remove the middle filter, what will be the light intensity at point C?

Unpolarized light consists of waves vibrating in multiple planes perpendicular to the direction of propagation. When such light passes through a polarizing filter, it becomes polarized, meaning it vibrates in a single plane. Understanding this transformation is crucial for analyzing how light intensity changes through polarizing filters.

Malus's Law describes how the intensity of polarized light changes as it passes through a polarizing filter. The intensity I of light after passing through a filter is given by I = I0 * cos²(θ), where I0 is the initial intensity and θ is the angle between the light's polarization direction and the filter's axis. This law is essential for calculating the intensity at point C after removing the middle filter.

Polarizing filters allow light waves vibrating in a specific direction to pass through while blocking others. When multiple filters are used, the orientation of each filter's axis relative to the previous one affects the resultant light intensity. Understanding how these filters interact is key to determining the final intensity at point C when the middle filter is removed.