91Ó°ÊÓ

In cases (a), (b), and (c), the light rays are initially in phase.

The phase difference between two light waves traveling through mediums relies upon the indexes of refraction of mediums, the wavelength of light waves, and the path length of each wave.

The phase difference formula between two waves traveling in the same direction is given by,

$N_2-N_1=\frac{L_2{n}_2}{\mathrm{λ}}-\frac{L_1{n}_1}{\mathrm{λ}}$

…(1)

Here, N₁ is the phase of ray 1, N₂ is the phase of ray 2, L is the path length of ray 1, L₂is the path length of ray 2, n₁ is the refractive index of medium 1, n₂is the refractive index of medium 2 and$\mathrm{λ}$ is the wavelength of the light ray.

From the figure, the path lengths and direction of both rays are the same and the medium is also the same. So, putting L₂= L₁ = L and n₂ = n₁ = n in equation (1),

$\begin{array}{l}{N}_2-N_1=\frac{Ln}{\mathrm{λ}}-\frac{Ln}{\mathrm{λ}}\\ N_2-N_1=0\end{array}$

Hence, the waves are likely to end up in phase.

From the figure, the value of path length is different while the direction of both rays and the medium is the same. So, putting $L_2≠L_1$and n₂ = n₁ = n in equation (1),

$\begin{array}{l}{N}_2-N_1=\frac{L_{2}n}{\mathrm{λ}}-\frac{L_{1}n}{\mathrm{λ}}\\ N_2-N_1=\frac{n}{\mathrm{λ}}\left(L_2-L_1\right)\end{array}$

Hence, the waves are not likely to end up in phase.

From the figure, the value of the path length of both rays is the same while the direction of both rays is opposite to each other in the same medium. So, putting L₂= L₁ = L and n₂= n₁= n in equation (1),

$\begin{array}{l}{N}_2-N_1=\frac{L_{2}n}{\mathrm{λ}}-\left(-\frac{L_{1}n}{\mathrm{λ}}\right)\\ N_2-N_1=\frac{n}{\mathrm{λ}}\left(L+L\right)\\ N_2-N_1=\frac{2Ln}{\mathrm{λ}}\end{array}$

Hence, the waves are likely to end up in phase.