![]() ![]() There will be a formation of value at the bending point of the two waves. Let us consider the parallel rays that bend at an angle with the slit. Bending makes the wave travel much longer than the other wave. Its working includes the interference of secondary waves with one another when they bend around the slit. As a result, a diffraction pattern is created from a single source. The interference pattern given above can be generated depending on the interference of two completely different waves that emanate from two dissimilar slits. Commonly, the ripples get approximated using parallel lines because the waves can be seen as straight lines since the screen is kept far away.īased on Huygens’ principle, it is proved that all the points between the edges act as sources of waves. While doing so, they seem to spread, causing mimic ripples. See the following figure to understand it better:Īs discussed earlier, the waves can bend and change their direction. On the other hand, if the slit is narrow, the light can be spectacularly diffracted. As a result, a bright spot is illuminated on the screen. The light will pass without touching if the slit’s width is very large. When the wavelength of the light is larger or similar to the obstacle, there produces a diffraction pattern. Two conditions need to be fulfilled to ensure the phenomenon is observable. ![]() We call this diffraction pattern because the light is diffracted (where it is painted). ![]() But, unlike the pattern produced by two slits, the light’s intensity does not seem to be distributed evenly in a single slit. It is a phenomenal discovery because it also helps produce the pattern using a single slit. The addition doubled the region’s luminosity while the negation rendered the region fully dark. In addition, when a ripple peak interferes destructively with another one, it can form a dark band. Here, one ripple’s peak interferes with another’s. He said such a pattern could only be formed by waves interfering with one another.Ī bright band is created while squeezing two waves between the slits. He proved that it is impossible to bend light or make it flow around an obstacle unless it obeys the Huygens principle. This discovery by Thomas Young vindicated Huygens. We call squeezed light an interference pattern, which can be seen as a uniform, alternating pattern of dark and bright bands. He made light squeeze through two slits kept adjacent to one another. However, he failed to illustrate the light’s wave nature, making it impossible for him to claim his achievement experimentally.Īfter nearly a decade, there came Thomas Young, a very enthusiastic British polymath who successfully illustrated the behaviour of light. He postulated a principle named Huygens’ Principle, stating that each point on a light wave could act as a source for a secondary wave capable of travelling at the same speed as light.įurthermore, he managed to explain the optical phenomena occurrence, namely reflection and refraction, using his light wave theory. His statement was contradictory to Newton’s beliefs. ![]() He suggested that the light behaves like a wave. In the 17 th century, a Dutch mathematician named Christian Huygens declared that light is not capable of behaving like a particle. This article will deeply discuss the diffraction phenomenon while explaining other related concepts and topics. In many cases, especially when an obstacle is very large, the stream of light does not flow around it. Moreover, it does not necessarily mean that the light stream must flow around the obstacle. Here, the light acts like water, which flows around the obstruction to reach our eyes. What is diffraction? Diffraction is the phenomenon that enables the light radiated by a source to be easily detectable even though there is an obstacle in between. Diffraction, polarisation and interference are the three major concepts essential for light wave nature. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |