In Young's double slit experiment the two slits are d distance apart. Interference pattern is observed on a screen at a distance D from the slits. A dark fringe is observed on the screen directly opposite to one of the slits. The wavelength of light is
Updated On: Jul 6, 2022
$\frac{D^2}{2d}$
$\frac{d^2}{2D}$
$\frac{D^2}{d}$
$\frac{d^2}{D}$
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The Correct Option isD
Solution and Explanation
We have the Young's double slit experiment given by
From the question, we see that the distance between the slits is equal to $d$ and the distance between the slit and screen is equal to $D$.
Hence for the nth dark fringe, we have $ (2n -1) \frac{D \lambda}{2d} = \frac{d}{2}$
Hence, we get $\lambda = \frac{d^2}{(2n - 1)D} = \frac{d^2}{D} \, for \, n = 1$
Wave optics are also known as Physical optics which deal with the study of various phenomena such as polarization, interference, diffraction, and other occurrences where ray approximation of geometric optics cannot be done. Thus, the section of optics that deals with the behavior of light and its wave characteristics is known to be wave optics.
In wave optics, the approximation is carried out by utilizing ray optics for the estimation of the field on a surface. Further, it includes integrating a ray-estimated field over a mirror, lens, or aperture for the calculation of the transmitted or scattered field.
Wave optics stands as a witness to a famous standoff between two great scientific communities who devoted their lives to understanding the nature of light. Overall, one supports the particle nature of light; the other supports the wave nature.
Sir Isaac Newton stood as a pre-eminent figure that supported the voice of particle nature of light, he proposed a corpuscular theory which states that “light consists of extremely light and tiny particles, called corpuscles which travel with very high speeds from the source of light to create a sensation of vision by reflecting on the retina of the eye”.
