There are several ways to produce polarized light. Optical processes reflection or refraction can be easily used to achieve that.
When unpolarized light rays travel through a dielectric or insulating material, reflected and refracted light rays from the flat surface are mostly partially polarized.
The amount of reflected light is specified by the optical properties of the reflecting surface, such as plastic sheets, glass, or highways.
The incident angle of the incoming electromagnetic lightwave and refractive indices of media in which light travels through them have an essential role in the polarization degree of the reflected and refracted polarized light beams.
You can see the reflection and transmission of unpolarized light with most of the incident angle (𝜃) values below.
When the incident ray travels from a less dense medium (n1) to a higher dense medium (n2) with a critical angle (𝜃_B), the reflected ray is perfectly s-polarized in which the orientation of the electric field vectors are perpendicular to the plane of incidence. Otherwise, the refracted beam has a 90-degree polarization angle, partially p-polarized. This critical angle is called a Brewster angle or polarization angle and is represented by 𝜃_B in the scheme below.
Brewster angle can be easily calculated using refractive indices of traveling media of light. In our experiment, we used air (n1 = 1) as the first medium in which light comes first and reflects in this part and microscope slide glass (n2 = 1.5) as the second medium, and the light transmits through. When we calculate the Brewster angle for our experiment, it equals approximately 57 degrees, and we can find the equation below.
Name | Properties | Price | Link | # |
---|---|---|---|---|
4×4 Baseplate | Skeleton of the System | 21.79 € | Base-plate | 1 |
MODULE: Polarizer Cube | It holds the linearly polarizing filter | 4.31 € | Linear Polarizer | 1 |
MODULE: Kinematic Microscope Slide Holder | It is used to insert the microscope slide with Brewster angle (53 degrees) | 3.7 € | Microscope Slide Holder | 1 |
MODULE: Laser Cube | LASER source holder | 17.68 € | Light Source | 1 |
EXTRA MODULE: Screen Holder Cube | It holds the Display Screen (Not Used in Practice) | 1 € | Screen | 1 |
- 1 × Base-plate 4×4
- 3 × Cube base 1×1
- 3 x Cube lid 1×1
- 1 × Polarizer Guide
- 1 × Polarizer Wheel
- 1 × Polarizer Lid
- 1 × Kinematic Slide Holder - Base
- 1 × Kinematic Slide Holder - Plate
- 1 × Kinematic Slide Holder - Clamp
- 2 × Laser Holder
- 1 x Laser Clamp
Extra Holder Parts but NOT USED in our experiment: - 1 x Sample Holder - comb
- Check out the RESOURCES for more information!
- 1 × Linear Polarizing Sheet 🢂
- 67 × 5 mm Ball magnets 🢂
- 28 x Screws DIN912 ISO 4762 - M3×12 mm 🢂
- 3 x Screws DIN912 ISO 4762 M2×16 mm 🢂
- Microscope Rectangular Coverslips 🢂
- 1 × 5 mW Blue UV Laser Pointer 🢂
- Baseplate
- Linear Polarizer Cube
- Microscope Slide Holder Cube : Brewster Angle Cube has same assembling procedure with Kinematic Mirror Holder 45 degrees.
- LASER Holder Cube
EXTRA MODULES: - Sample Holder for Screen
All necessary parts to assemble a Microscope Slide Glass Holder Module be gathered in the image below:
Brewster's angle experiment setup can be prepared easily. After printing and assembling the module parts, we try to find a critical angle or Brewster's angle as much as we can.
In this setup, we use LASER as a light source because it is easier to observe the polarization degree changes by reflection. As a first step, LASER light beams reflect from microscope slide glass and pass through a linear polarizer. Then a piece of paper is inserted on the sample holder comb. Finally, we can observe the totally polarized reflected light.
We should make a good alignment to find the Brewster angle as the incidence angle of the incoming light. In practice, it is hard because of using screws, we could not find the exact incidence angle of a microscope slide. Nevertheless, I could take results that are almost perfectly polarized light after reflection in almost critical angle.
You can see the reflected laser light beam without alignment at a random incident angle above.
In the image below, the incoming beam is reflected with almost Brewster angle, 57 degrees for microscope slide glass:
Let's look at our almost perfectly polarized light by reflection experiment video records. The orientation direction of the linear polarizer only changes in 1st and 2nd videos, and we see that reflected light is totally polarized almost. The light is blocked, and we can see almost no light after the polarizer when the orientation of the linear polarizer is perpendicular to the polarization orientation of the reflected beam.
We are open to new ideas. Please contribute to the project freely, this place is a free country which is built by codes and machines 🤖