Understanding Polarization & Wire Grid Polarizers To understand the function of wire grid polarizers, one must first understand polarization of light. Light is most commonly characterized by its frequency (or wavelength) and intensity. In the visible spectrum, the wavelength is related to the color of light, whereas intensity represents its brightness. These are two typical properties for common applications such as lighting in your home or car. However, there are other applications that exploit another important characteristic of light called polarization. When we invoke classical electrodynamics, light is an electromagnetic wave comprised of an electric and a magnetic field. These fields oscillate in space and time depending on the wavelength and frequency, respectively. The electric field (E) is perpendicular to the magnetic field (B), and both oscillate perpendicular to the direction of propagation. When the electric field oscillates randomly, we call that light unpolarized (and this is what we mostly observe around us).
Light Polarization For light to be polarized, electric (or magnetic) field oscillation needs to be confined to a single plane or follow a helical trajectory along with direction of propagation. Basically, the plane of oscillation needs to be well-defined or non-random for the light to be termed as polarized. When the oscillation is confined to a single plane, the light is linear polarized. Here, the plane can either be aligned with, or have a tilt with respect to, the vertical plane. When the oscillation follows a helical pattern, the light is circularly polarized. Depending on the direction of the helical trajectory, we can either have right or left circularly polarized light. When the helix traces an ellipse instead of a circle, the light is elliptically polarized. In all these cases, we see that the electric field oscillation follows a certain well-defined trajectory and is not random.