What is Brewster Law?
We all know that all reflected lights don’t get polarized. In the plane of the medium, light is polarized at 90° to a plane that supports more reflection. When the light shines at a particular angle, it creates a huge impact on how polarized reflection is going to be. Therefore, Brewster’s law is here to guide us as to how the polarization varies with angle or simply the Brewster angle.
Now, we will understand Brewster law and Brewster angle in detail.
State Brewster Law
So, we understood the brief of what is brewster law, now understand it in detail:
The maximum polarization occurs at an angle of 90° according to the Brewster law occurs between reflected and refracted rays. In 1811, a famous Scottish Physicist, Sir David Brewster, discovered this, and the law was named after him. Besides, the polarizing angle is known as Brewster's angle.
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According to the Brewster law, we obtain the highest order of polarization of light by letting the rays come in contact with the surface of a transparent medium. Here, the refracted surface is perpendicular to the reflected ray, and a relationship develops between the polarizing angle ‘iP’ and the refractive index.
Point To Remember
The point to be noted is that the tangent of the polarizing angle is numerically equal to the medium's refractive index.
When we introduce a certain angle of incidence, a polarizing angle forms, the reflecting light gets entirely polarized. Here, a certain angle of incidence is known as a polarizing angle. On the surface of transparent material, the polarizing angle ‘iP’ attaches to the refractive index ‘μ’ of the material.
Brewster Law Formula
We express the relation for polarising angle formula as μ = tan ip
Here,
μ refers to the refractive index of transparent medium
ip is the polarizing angle of incidence or a Brewster angle
When unpolarized light is incident on a transparent medium at any polarizing angle, then rays that transfer and reflect are vertical to each other.
Further, we see that as = \[\frac{(sinip)}{(Sin r)}\]
Therefore, tan ip (polarizing angle) = \[\frac{(sinip)}{(Sin r)}\]
The above equation describes polarization by reflection.
Brewster Angle Derivation
In his experiment, Brewster found that the reflected and refracted rays are orthogonal to each other when light is incident at a polarizing angle. Mathematically, the above statement can be written as;
ip+ 900 + r =1800
r = 900 - ip
From Snell's law, sini/sinr =μ
Sinip/sin(90−ip) =μ
Or,
μ = tanip
We have proved the above statement that the tangent of the polarizing angle is numerically equal to the refractive index of the medium.
Brewster's Angle
A Brewster angle is the angle at which an incident beam of unpolarized light gets reflected after the complete polarization is known as the Brewster angle or polarizing angle.
When an incident light with an electric field is parallel to the plane of incidence, you usually get zero reflection coefficients at an angle between 0 and 90°.
Because of this, the polarizing angle gets linearly polarized by having its electric field vectors parallel to the plane of the reflecting surface and perpendicular to the plane of incidence. At other angles, the reflected lights get partially polarized.
With the help of the Brewster law, the magnitude of Brewster's angle deviation depends upon the refractive indices of the involved optical channel and can be calculated.
So, what is the Brewster angle?
What Is Brewster Angle?
B = arc tan(n2/n1)
Where n1 is the refractive index of the medium through which light propagates and n2 is the refractive index of the medium through which light reflects. It can also be shown that the sum of the angles in both media (relative to a direction for normal incidence) is 90°
By using the following equation, Brewster’s angle can be calculated as given below:
n = sin(qi)/sin(qr) = sin(qi)/sin(q90-i) = tan(qi)
Here,
n is the refractive index of the light reflecting medium
qr is the angle of refraction
qi is the angle of incidence
The above equation is useful for determining the refractive index of an unknown specimen such as opaque material with a high absorption coefficient for light transmission.
The critical Brewster angles for glass, water, and diamond are 57°, 53°, and 67.5°, respectively.
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From the above arrangement, to obtain the disappearing reflection losses at the Brewster plate, the angle of incidence and Brewster's angle must be coincident, and light must be polarized, i.e., the direction of polarization should be in the plane of incidence (here, we have a drawing plane).
The light reflected from the surface at Brewster's angle produces shining effects. In modern lasers, Brewster's angle is an important concept to create linearly polarized light by reflections at the mirror surface of the laser cavity.
Fun Fact
When you go hiking, you wear polarized sunglasses. When the weather is sunny, you might have noticed a beautiful scene of reflection on the lake.
The above two are polarized reflections. However, when you see through your sunglasses, you notice that the reflections fade. This happens because the sunglasses are polarized, which enables only polarized light to go through them. Also, you will find polarizers in monitors and TV screens to reduce the glare on sunny days.
FAQs on Brewster Law
1. What is Brewster's Law in simple terms?
Brewster's Law states that if unpolarised light hits a transparent surface at a specific angle, called Brewster's angle (or the polarising angle), the reflected light will be completely plane-polarised. The tangent of this angle is equal to the refractive index of the medium.
2. How do you calculate Brewster's angle for a material?
You can calculate Brewster's angle (i_p) using a simple formula that connects it to the refractive indices of the two media. The formula is: tan(i_p) = n₂ / n₁, where n₁ is the refractive index of the initial medium (like air) and n₂ is the refractive index of the medium the light is entering (like glass or water).
3. What are some real-world examples of Brewster's Law?
Brewster's Law has several practical applications you might see every day. These include:
- Polarised Sunglasses: They use this principle to block the glare (which is horizontally polarised light) reflected from surfaces like roads and water, making it easier to see.
- Photography: Photographers use polarising filters on their camera lenses to reduce reflections from windows or water surfaces for clearer shots.
- Lasers: It is used in devices called Brewster windows to ensure light of a specific polarisation passes through with minimal loss.
4. Why does the reflected light become fully polarised only at Brewster's angle?
This happens because at Brewster's angle, the reflected ray and the refracted ray are exactly 90 degrees apart. At this specific orientation, the electrons oscillating in the transparent medium cannot produce a reflected wave with electric field vibrations in the plane of incidence. As a result, only the light with vibrations perpendicular to the plane of incidence is reflected, making it perfectly plane-polarised.
5. What happens if light strikes a surface at an angle other than Brewster's angle?
If the angle of incidence is not equal to Brewster's angle, the reflected light will be partially polarised, not completely polarised. This means it will contain a mix of light waves with vibrations in different directions, but with a higher concentration of waves vibrating perpendicular to the plane of incidence.
6. How is Brewster's Law different from Malus's Law?
Brewster's Law and Malus's Law both deal with polarisation, but they describe different processes.
- Brewster's Law explains how unpolarised light can become polarised through reflection off a surface.
- Malus's Law, on the other hand, describes what happens when light that is already polarised passes through another polarising filter (an analyser). It helps calculate the intensity of the light that gets through.
7. Does Brewster's Law apply when light travels from a denser medium to a rarer medium?
Yes, Brewster's Law applies in this case as well. For example, when light travels from water (denser) to air (rarer), there is still a specific Brewster's angle at which the reflected light will be completely plane-polarised. The formula remains the same, but the values of n₁ and n₂ are swapped, where n₁ is now the refractive index of the denser medium.
