Light: Multiple Refractions
Key Concepts
- Multiple Refractions
- Normal Incidence
- Refractive Index
Introduction:
A light ray bends when it travels from one medium to another, and it bends either towards or away from the imaginary normal line while doing so. When the light ray traveling in the air enters a glass slab or water, it bends towards the normal. And, when it is traveling in the glass or water and enters the air, it bends away from the normal. In this section, we will be throwing some light on the kind of refraction that a light ray undergoes when it encounters more than two mediums.
Explanation
Multiple refractions:
A ray of light undergoes multiple refractions when it encounters more than one transparent mediums one after the other. At every step, it either bends towards or away from the normal depending upon the refractive indices of the current and the upcoming medium.
For example,
When a light ray falls on the water in a glass tumbler, it undergoes many refractions so that it comes out of it from the bottom. The light refracts,
- From air to water
- Then from water to the glass base of the tumbler
- Finally, from the glass base back to the air from the bottom of the tumbler
Note: Bending of light
Suppose the refractive indices of two mediums be n1 and n2.
- If n1 < n2, then the refracted ray bends towards the normal.
- If n2 > n1, then the refracted ray bends away from the normal.
Explanation:
Refractive index of air (1) is smaller than that of water (1.33), i.e., at the air-water interface,
nair < nwater
Thus, the refracted ray bends towards the normal.
Refractive index of water (1.33) is smaller than that of glass (1.5), i.e., at the water-glass interface,
nwater < nglass
Thus, the refracted ray bends towards the normal again.
Refractive index of water (1.33) is smaller than that of glass (1.5), i.e., at the glass-air interface,
nair < nglass
Thus, the refracted ray bends away from the normal.
When the light ray enters the tumbler from the bottom, it gets refracted in the following way:
At the air-glass interface,
nair < nglass
Thus, the refracted ray bends towards the normal.
At the glass-water interface,
nglass > nwater
Thus, the refracted ray bends away from the normal.
At the water-air interface,
nwater > nair
Thus, the refracted ray bends away from the normal.
Normal incidence:
A light ray incident normally on the glass surface goes straight into all the mediums along the normal line and emerges without any deviation from its path.
Note:
In all the above refractions, the emergent ray is parallel to the incident ray, even if a light ray suffers multiple refractions before emerging into the first medium (air).
Question:
Kerosene and water have refractive indices of 1.44 and 1.33, respectively. Kerosene floats on the top of water, as shown. A light ray from the air enters the kerosene, then the water and then back to the air. Identify the way in which the light ray would bend in every step? Is the emergent ray parallel to the incident ray?
Answer:
Given that,
The refractive index of kerosene, nk = 1.44.
The refractive index of water, nw = 1.33.
And the refractive index of air, na = 1.
nk > na
Thus, the refracted ray bends towards the normal.
At the kerosene-water interface,
nk > nw
Thus, the refracted ray bends away from the normal.
At the water-air interface,
nw > na
Thus, the refracted ray bends away from the normal.
Yes, the emergent ray E is parallel to the incident ray I.
Summary:
- A ray of light undergoes multiple refractions when it encounters more than one transparent mediums one after the other.
- At every step, it either bends towards or away from the normal depending upon the refractive indices of the current and the upcoming medium.
- However, during normal incidence, the ray of light does not bend at all. It passes straight through all the mediums.
- Even though a ray of light undergoes multiple refractions, it emerges out parallel to the incident ray into the first medium.
Related topics
Velocity Time Graphs – Definition, Examples
Key Concepts 1. Velocity-time graph 2. Slope of v-t graph = acceleration 3. Types of velocity-time graphs 4. Displacement from v-t graphs What is Velocity Time Graph A velocity time graph is a simple graph that shows you how the velocity of an object changes with time. In this graph: It tells us: You can […]
5 Types Of Mechanical Layers Of The Earth
Composition Layer of the Earth When we are studying the layers of the Earth, it can be divided into two ways. One is by how they move, which is the mechanical layers. The other is by what they are made of. This second way involves the composition of layers of the Earth. Based on the […]
Effects of Force: Types, Examples, and Applications
Effects of Force Key Concepts What Is Force? A force comes into play when two or more objects interact with each other. This force when applied to an object by another, gives rise to some kind of change in the state of motion of an object. In this section we will be looking at these […]
Electrical Components and Symbols Explained with Diagrams
What Are Electrical Components? Consider the electrical components as the building blocks of any circuit. These are the actual components that cause electricity to do what you want it to do. Every switch you flip, every fan that spins, every charger that doesn’t overheat relies on these small parts doing their job quietly. You rarely […]
Other topics
Comments: