91Ó°ÊÓ

The wavelength, $\mathrm{λ}=589\text{nm}$.

The angular separation, ${\mathrm{θ}}_1=0.20°$.

The refractive index of water, $n=1.33$.

Young's double-slit experiment. When monochromatic light passing through two narrow slits illuminates a distant screen, a characteristic pattern of bright and dark stripes is observed. This interference pattern is caused by the superposition of overlapping light waves originating from the two slits.

The condition for the maxima in Young’s experiment is given as follows.

$d\sin \mathrm{θ}=m\mathrm{λ}$ …… (1)

Here, d is the distance between the slits, $\mathrm{λ}$ is the wavelength, m is the order and $\mathrm{θ}$is the angular separation.

The expression to calculate the wavelength in the vacuum is given as follows.

${\mathit{λ}}_{\mathbf{n}}\mathbf{=}\frac{\mathbf{λ}}{\mathbf{n}}$ …… (2)

Calculate the distance between the slits.

Substitute 1 for m, $0.{20}^{0}C$for ${\mathrm{θ}}_1$and $589\text{nm}$for $\mathrm{λ}$into equation (1).

$d\sin \left(0.20\right)=1×589×{10}^{-9}$

$$\begin{gathered} d=\frac{589×{10}^{-9}}{\sin \left(0.20\right)} \\ =1.687×{10}^{-4}\text{m} \end{gathered}$$

Calculate the wavelength in the water.

Substitute $589\text{nm}$for $\mathrm{λ}$into equation (2).

$$\begin{gathered} {\mathrm{λ}}_n=\frac{589×{10}^{-9}}{1.33} \\ =442.85×{10}^{-9}\text{m} \\ =442.85\text{nm} \end{gathered}$$

Calculate the angular separation when the arrangement immerged in water.

Substitute $1.687×{10}^{-4}\text{m}$ for d, $442.85\text{nm}$for ${\mathrm{λ}}_n$and 1 for m into equation (1).

$$\begin{gathered} 1.687×{10}^{-4}×\sin \left({\mathrm{θ}}_2\right)=1×442.85×{10}^{-9} \\ \sin {\mathrm{θ}}_2=\frac{442.85×{10}^{-9}}{1.687×{10}^{-4}} \end{gathered}$$

$$\begin{gathered} {\mathrm{θ}}_2={\sin }^{-1}\left(2.62×{10}^{-3}\right) \\ =0.15° \end{gathered}$$

Hence, the angular separation when the arrangement immerged in water $0.{15}^{0}C$.