Total Internal Reflection - Definition, Formula, Example, FAQs

Edited By Vishal kumar | Updated on Jul 02, 2025 04:38 PM IST

Define total internal reflection using an example.

Consider the case below. A ray of light travels from a watery medium to air. The light ray will be refracted at the point where the two mediums meet. The refracted light ray bends away from the normal as it passes from a medium of a higher refractive index to one of a lower refractive index. The angle of incidence at which the refraction angle is 90 degrees is called the critical angle. The incident ray will reflect back to the medium when the angle of incidence is larger than the critical angle. This is known as total internal reflection.

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Define total internal reflection using an example.
Total internal reflection formula
Total internal reflection examples

Total Internal Reflection - Definition, Formula, Example, FAQs

Total internal reflection critical angel

When Does Total Internal Reflection Occur?

Consider two lights passing through an optically denser media and into an optically rarer material at specific points.

The refraction of light is the phenomenon that causes light to bend off its normal path. This is a unique situation in which the refracted angle exceeds the incident angle.

The above statement describes how increasing the angle of incidence causes the angle of refraction to increase.

There is still a moment where the refraction angle becomes perpendicular. The refracted light will become parallel to the interface as a result of this.

The refracted ray angle of the rarer medium corresponds to the incident ray angle of the denser medium, which is 90°. This is called the critical angle of total internal reflection (c).

The ray returns to the same medium when it is incident on the surface at an angle larger than the critical angle. Total internal reflection refers to the full process of returning a light beam away from a denser medium. So total internal reflection occurs when the incidence angle is greater than the critical angle.

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Conditions for total internal reflection of light

There are two primary factors that influence whether or not the phenomena of total internal reflection occurs. (TIR) is founded on. A little difference in the two circumstances may not yield the desired effect.

There are two prerequisites for total internal reflection:

Light incident at the interface of two different media should prefer to pass from a denser to a rarer medium.
For these two media, a larger angle of incidence is required than the critical angle.

Total internal reflection of light formulas:

Total internal reflection formula

Snell's Law: $n_{1} \sin i = n_{2} \sin r$
Critical Angle Formula: $Θ_{crit} = \sin^{- 1} (\frac{n_{2}}{n_{1}})$

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Total internal reflection examples

Here are some examples of total internal reflection:

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Total internal reflection in optical fiber

One of the most important applications of total internal reflection is seen in optical fiber. In an optical fiber, the total internal reflection approach is used. The core of the higher refractive index fiber contains the inner component of the fiber. Another layer of glass surrounds all of these fibers. They have a refractive index that is just below that of the lower refractive index. The fibers are protected by a plastic jacket.

When light from one end of the core goes toward the cladding and propagates through it, this is known as back to back total internal reflection. Optical fibers have a lot of uses in the medical field, especially for endoscopy.

Total internal reflection in optical fiber

Define Acceptance angle:

The acceptance angle of an optical fiber is determined by ray optics is the maximum angle of a ray striking the fiber core (against the fiber axis) that allows incident light to be directed by the core. The numerical aperture is defined as the sine of that permissible angle (assuming an incident ray in air or vacuum) and is mostly governed by the refractive index contrast between the core and cladding of the fiber (assuming an incident ray in air or vacuum):

Acceptance angle formula

$θ_{acc} = \frac{1}{n_{0}} \sqrt{n_{core}^{2} - n_{cladding}^{2}}$

n₀ = refractive index of the medium around the fibre

n_core = refractive index of core

n_cladding = refractive index of cladding

θ_a_cc= acceptance angle

Diamond:

Total internal reflection in diamond: The incident ray is greater than the critical angle when it falls on every face of the diamond. The diamond's critical value is 23°. This situation is responsible for a diamond's entire internal reflection, which causes it to shine.

Diamond

Mirage:

It's an optical illusion that causes the water layer to appear at short distances in the desert or on the road. Total internal reflection, which happens as a result of atmospheric refraction, is an example of a mirage.

Mirage

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NCERT Physics Notes:

Frequently Asked Questions (FAQs)

1. What is total internal reflection?

Total internal reflection definition: TIR (total internal reflection) is an optical phenomenon in which waves, such as light, are entirely reflected when they reach the boundary between two mediums, such as air and water, under particular conditions. When waves travelling in one medium collide with another medium with a higher wave speed (lower refractive index), they are not refracted into the second ("external") medium but are entirely reflected back into the first ("internal") medium.

2. What is total internal reflection?

Total internal reflection is an optical phenomenon that occurs when light traveling in a denser medium hits the boundary with a less dense medium at an angle greater than the critical angle. In this case, all the light is reflected back into the denser medium, with no light passing through to the less dense medium.

3. What is the full form of TIR?

Full form of Total internal reflection

4. The glass with the refractive index n1 = 1.5 is surrounded by another glass with the refractive index n2. Determine the refractive index n2 if the critical angle for total internal reflection between the two is 80°.

θ= 80°

n1 = 1.5

sinθ= n2/n1

n2= n1 × 80°

n2 = 1.48

5. Write one application of total internal reflection.

Total internal reflection of light is used in optical fibers.

6. What is the difference between partial and total internal reflection?

Partial internal reflection occurs when some light is reflected and some is refracted at the boundary between two media. Total internal reflection occurs when all light is reflected back into the original medium, with no refraction occurring.

7. Can sound waves undergo total internal reflection?

Yes, sound waves can undergo total internal reflection. This phenomenon can occur at the boundary between two media with different sound velocities, such as warm and cold layers of air in the atmosphere.

8. Can total internal reflection occur in a vacuum?

No, total internal reflection cannot occur in a vacuum. It requires two media with different refractive indices, and a vacuum has a refractive index of 1, which is lower than any material medium.

9. How does total internal reflection affect the apparent depth of a swimming pool?

Total internal reflection can make a swimming pool appear shallower than it actually is. Light rays from the bottom of the pool that would normally reach an observer's eyes at steep angles are totally internally reflected at the water-air interface, reducing the apparent depth of the pool.

10. Can total internal reflection occur when light travels from air to water?

No, total internal reflection cannot occur when light travels from air to water. It only happens when light travels from a denser medium (like water) to a less dense medium (like air).

11. How does a fiber optic cable work?

Fiber optic cables use the principle of total internal reflection to transmit light signals over long distances. The light travels through a core of glass or plastic surrounded by a cladding with a lower refractive index, causing the light to repeatedly reflect off the inner walls of the fiber without escaping.

12. What happens to the intensity of light during total internal reflection?

During total internal reflection, 100% of the light is reflected back into the original medium. There is no loss of intensity due to transmission or absorption at the boundary, making it an extremely efficient reflection process.

13. Why does a diamond sparkle more than glass?

Diamonds sparkle more than glass because they have a higher refractive index, which results in a smaller critical angle. This means that more light undergoes total internal reflection within the diamond, leading to increased brilliance and sparkle.

14. How does total internal reflection differ from regular reflection?

Total internal reflection occurs only at the interface between two media when light travels from a denser to a less dense medium above a critical angle. Regular reflection can occur at any angle and at any interface, but some light is usually transmitted as well.

15. How is the critical angle calculated?

The critical angle (θc) can be calculated using Snell's law: sin(θc) = n2/n1, where n1 is the refractive index of the denser medium and n2 is the refractive index of the less dense medium.

16. What is the relationship between the critical angle and the refractive indices of two media?

The critical angle (θc) is related to the refractive indices of the two media by the equation: sin(θc) = n2/n1, where n1 is the refractive index of the denser medium and n2 is the refractive index of the less dense medium. As the ratio n2/n1 decreases, the critical angle decreases.

17. What conditions are necessary for total internal reflection to occur?

Two conditions must be met for total internal reflection: 1) Light must be traveling from a denser medium to a less dense medium (e.g., from glass to air). 2) The angle of incidence must be greater than the critical angle for the two media involved.

18. What is the critical angle?

The critical angle is the smallest angle of incidence at which total internal reflection occurs. When light strikes the boundary at exactly the critical angle, it will travel along the boundary between the two media rather than reflecting or refracting.

19. How does the angle of incidence affect total internal reflection?

For total internal reflection to occur, the angle of incidence must be greater than the critical angle. As the angle of incidence increases beyond the critical angle, all light is reflected back into the denser medium.

20. What is the principle behind a corner reflector?

A corner reflector uses multiple total internal reflections to return light in exactly the opposite direction from which it came. It typically consists of three mutually perpendicular reflective surfaces, ensuring that any incoming light is reflected back parallel to its original path.

21. How do mirages form, and what role does total internal reflection play?

Mirages form due to the refraction of light in layers of air with different temperatures and densities. While not strictly total internal reflection, the principle is similar. Light bends away from the hotter, less dense air near the ground, creating an illusion of a reflective surface.

22. What is the significance of Brewster's angle in relation to total internal reflection?

Brewster's angle is the angle of incidence at which light with a particular polarization is perfectly transmitted through a transparent medium, with no reflection. While not directly related to total internal reflection, both concepts involve the behavior of light at interfaces between media.

23. How does total internal reflection contribute to the formation of caustics?

Caustics are patterns of light formed when rays are reflected or refracted by a curved surface. While caustics can form through regular reflection and refraction, total internal reflection can contribute to their formation in transparent objects, creating complex light patterns.

24. What is the role of total internal reflection in the formation of glory rings?

Glory rings, the colorful rings sometimes seen around shadows cast on clouds, involve a combination of diffraction, reflection, and refraction. While not the primary mechanism, total internal reflection within water droplets can contribute to the intensity and pattern of glory rings.

25. How does total internal reflection contribute to the phenomenon of whispering galleries?

Whispering galleries, where sound can be heard clearly at distant points along a curved wall, are primarily an acoustic phenomenon. However, the principle is analogous to total internal reflection of light, where sound waves are repeatedly reflected along the curved surface, concentrating the sound at certain points.

26. How does total internal reflection contribute to the formation of rainbows?

Total internal reflection plays a role in rainbow formation within water droplets. After light enters a raindrop and is refracted, it is reflected off the back of the droplet. For certain angles, this reflection is total internal reflection, contributing to the intensity of the rainbow colors.

27. Can total internal reflection occur between two solids?

Yes, total internal reflection can occur between two solids if one has a higher refractive index than the other and the angle of incidence is greater than the critical angle for those two materials.

28. How does total internal reflection affect the transmission of light in optical fibers over long distances?

Total internal reflection allows light to travel through optical fibers with minimal loss over long distances. The light bounces off the inner walls of the fiber repeatedly, maintaining its intensity and direction, which makes fiber optics ideal for long-distance communication.

29. What is the relationship between total internal reflection and evanescent waves?

During total internal reflection, evanescent waves are created in the less dense medium. These waves carry energy but do not propagate away from the interface. They decay exponentially with distance from the boundary and can be used in applications like near-field microscopy.

30. How does the wavelength of light affect total internal reflection?

The wavelength of light does not directly affect whether total internal reflection occurs. However, since the refractive index of a material can vary slightly with wavelength (dispersion), the critical angle may be slightly different for different colors of light.

31. Can total internal reflection be used to trap light within a material?

Yes, total internal reflection can be used to trap light within a material. This principle is used in optical waveguides and in some types of laser cavities, where light is confined within a medium by repeated total internal reflections.

32. How does total internal reflection relate to Snell's law?

Snell's law describes the relationship between the angles of incidence and refraction when light passes between two media. Total internal reflection occurs when Snell's law would require the sine of the angle of refraction to be greater than 1, which is physically impossible.

33. What is the role of total internal reflection in the design of prisms?

Prisms often use total internal reflection to change the direction of light beams or to separate light into its component colors. For example, right-angle prisms use total internal reflection to turn a light beam by 90 or 180 degrees.

34. How does total internal reflection affect the appearance of submerged objects when viewed from above?

Total internal reflection can cause submerged objects to appear distorted or partially invisible when viewed from above the water. This is because some light rays from the object that would reach the observer's eyes in air are instead totally internally reflected at the water-air interface.

35. Can total internal reflection occur in gases?

Yes, total internal reflection can occur in gases, although it's less common than in liquids or solids. It requires a boundary between two gases with different refractive indices, such as layers of air at different temperatures or densities.

36. How does total internal reflection contribute to the glitter of gemstones?

The high refractive index of many gemstones results in a low critical angle for total internal reflection. This means that much of the light entering the gem is totally internally reflected, bouncing around inside before exiting, contributing to the stone's brilliance and fire.

37. What is the difference between total internal reflection and total external reflection?

Total internal reflection occurs when light travels from a denser to a less dense medium at an angle greater than the critical angle. Total external reflection is a term sometimes used to describe the near-perfect reflection of certain wavelengths by multi-layer dielectric mirrors, which is a different phenomenon.

38. How does total internal reflection affect the design of solar concentrators?

Some solar concentrators use total internal reflection to guide and concentrate sunlight onto a smaller area of solar cells. This can increase the efficiency of solar panels by allowing them to capture light from a wider area.

39. Can total internal reflection be used to measure the refractive index of a material?

Yes, the phenomenon of total internal reflection can be used to measure the refractive index of a material. By determining the critical angle between the material and a reference medium (often air), the refractive index can be calculated using the relationship sin(θc) = n2/n1.

40. What is the role of total internal reflection in the creation of mirages?

While mirages are primarily caused by refraction, total internal reflection can play a role in some types of mirages. In a superior mirage, for example, light can be trapped between layers of air through a process similar to total internal reflection, creating inverted images.

41. How does total internal reflection contribute to the efficiency of LED lights?

In some LED designs, total internal reflection is used to direct light out of the semiconductor material. By shaping the LED and its encapsulation appropriately, more light can be extracted, increasing the overall efficiency of the device.

42. What is the relationship between total internal reflection and the concept of numerical aperture in fiber optics?

The numerical aperture of an optical fiber is related to the maximum angle at which light can enter the fiber and still undergo total internal reflection. It's determined by the refractive indices of the core and cladding and is a measure of the fiber's light-gathering ability.

43. How does total internal reflection affect the design of automobile reflectors?

Automobile reflectors often use the principle of total internal reflection to efficiently redirect light. The reflectors are designed with precise angles and surfaces to ensure that incoming light is totally internally reflected in the desired direction.

44. Can total internal reflection occur at the interface between two liquids?

Yes, total internal reflection can occur at the interface between two liquids if they have different refractive indices and the angle of incidence is greater than the critical angle for those two liquids.

45. What is the role of total internal reflection in the design of non-imaging optics?

Non-imaging optics, used in applications like solar collectors and illumination systems, often utilize total internal reflection to efficiently transfer light from a source to a target without forming an image. This allows for maximum light collection and transfer efficiency.

46. How does total internal reflection affect the propagation of surface plasmons?

Surface plasmons are electromagnetic waves that propagate along the interface between a metal and a dielectric. Total internal reflection in the dielectric medium is a key component in exciting these surface plasmons, which are used in various sensing and imaging applications.

47. Can total internal reflection be used to create optical switches?

Yes, optical switches can be designed using the principle of total internal reflection. By changing the refractive index of a medium or altering the angle of incidence, light can be switched between total internal reflection and transmission, creating an on-off switch for optical signals.

48. How does total internal reflection contribute to the phenomenon of light piping?

Light piping occurs when light is guided along a transparent material through repeated total internal reflections. This principle is used in applications ranging from illuminated signs to automotive lighting, where light needs to be transported along curved or complex paths.

49. What is the relationship between total internal reflection and the critical angle for different colors of light?

Due to dispersion, different colors of light have slightly different refractive indices in a material. This means that the critical angle for total internal reflection can vary slightly for different wavelengths, potentially leading to some color separation effects.

50. How does total internal reflection affect the design of retroreflectors?

Retroreflectors, such as those used in road signs and safety equipment, often use a combination of total internal reflection and regular reflection to return light directly back to its source. The precise geometry of the reflector ensures that light undergoes the necessary reflections to achieve this effect.

51. Can total internal reflection be used to create optical illusions?

Yes, total internal reflection can be used to create various optical illusions. For example, a clear object with the right shape and refractive index can appear to vanish when submerged in a liquid with a matching refractive index, due to the absence of reflection or refraction at the interface.

52. How does total internal reflection contribute to the efficiency of solar cells?

Some advanced solar cell designs use textured surfaces or specialized coatings that promote total internal reflection within the cell. This traps light inside the solar cell for longer, increasing the chance of absorption and improving overall efficiency.

53. How does total internal reflection affect the design of light pipes?

Light pipes use total internal reflection to transport light from a source to a desired location with minimal loss. The design of light pipes considers factors like material refractive index, pipe geometry, and surface quality to maximize the efficiency of light transmission through total internal reflection.

54. Can total internal reflection be used to create invisible materials?

While true invisibility is not possible, total internal reflection can be used to create materials that are highly transparent or that bend light in unusual ways. For example, some types of metamaterials use precisely designed structures that manipulate light through processes including total internal reflection to achieve unusual optical properties.