Young's double-slit experiment is conducted in water `(mu_(1))` as shown in figure and a glass plate of thickness t and refractive index `mu_(2)` is placed in the path of `S_(2)`. Find the magnitude of the optical path difference at 'O'.

A YDSE is conducted in water (mu_(1)) as shown in figure. A glass plate of thickness t and refractive index mu_(2) is placed in the path of S_(2) . The optical path difference at O is

A Young's double-slit experiment is conducted in water (n_(1)) as shown in the following figure, and a glass plate of thickness t and refractive index n_(2) is placed in the path of S_(2) . Wavelength of light in water is lambda . Find the magnitude of the phase difference between waves coming from S_(1) and S_(2) at O.

Young's double slit experiment is conducted in a liquid of refractive index mu_1 as shown in figure. A thin transparent slab of refractive index mu_2 is placed in front of the slit s_2 . The magnitude of optical path difference at 'O' is

When a thin transparent plate of thickness t and refractive index mu is placed in the path of one the two interfering waves of light, then the path difference changes by

When a transparent parallel plate of uniform thickness t and refractive index mu is interposed normally in the path of a beam of light, the optical path is

In a Young's double slit experimental arrangement shown here, if a mica sheet of thickness t and refractive indec mu is placed in front of the slit S_1 , then the path difference (S_1P-S_2P) is

In Young's double-slit experiment, let A and B be the two slit. A thin film of thickness t and refractive index mu is placed in front of A. Let beta = fringe width. Then the central maxima will shift

Light travels through a glass plate of thickness t and refractive index mu. If c is the speed of light in vacuum, the time taken by light to travel this thickness of glass is