If the refractive index of a material of an equilateral Prism is \(\sqrt{3}\), then angle of minimum deviation will be (A) \(50^{\circ}\) (B) \(60^{\circ}\) (C) \(39^{\circ}\) (D) \(\overline{49^{\circ}}\)

Snell's law defines the relationship between the angles of incidence and refraction for a wave passing through a boundary between two different isotropic media. In this case, the two media are air and the material of the equilateral prism. The angle of minimum deviation occurs when the light ray inside the prism has an equal angle of incidence and angle of emergent. For an equilateral prism, the total internal deviation will be equal to the sum of the angle of incidence and angle of emergence minus the angle of the prism. We will denote the angle of incidence as \(i\), angle of emergence as \(e\), refractive index of the material as \(μ\), and the angle of refractive deviation as \(δ\).

Using Snell's law, we can write the refractive index relationship between air and the material of the prism: \(μ = \frac{\sin i}{\sin r}\), where \(r\) is the angle of refraction. Since we are given the refractive index value as \(\sqrt{3}\), we can say: \(\sqrt{3} = \frac{\sin i}{\sin r}\)

For an equilateral prism, the angle of prism \(A\) is equal to \(60^{\circ}\). From the geometry of the prism, we know that: \(A = (\angle i - \angle r) + (\angle i' - \angle r')\), where \(i'\) and \(r'\) are the secondary incident and refracted angles respectively. Since the angle of minimum deviation occurs when \(\angle i = \angle i'\), we can simplify the equation: \(60^{\circ} = 2(\angle i - \angle r)\) Now, let's find the angle of minimum deviation, \(\delta\). \(\delta = \angle i + \angle i'- A\)

From previous steps, we have found that the refractive index equation is \(\sqrt{3} = \frac{\sin i}{\sin r}\), and the angle equation is \(60^{\circ} = 2(\angle i - \angle r)\). We can rewrite the angle equation as \(\angle i - \angle r = 30^{\circ}\). Now, \(\delta = 2\angle i - 60^{\circ}\). In an equilateral prism with minimum deviation, \(\angle i = \angle r\). So, \(\sqrt{3} = \frac{\sin i}{\sin i}\) Solving for \(i\), we get \(i = 39^{\circ}\). Finally, we calculate the angle of minimum deviation: \(\delta = 2\angle i - 60^{\circ} = 2(39^{\circ}) - 60^{\circ} = 78^{\circ} - 60^{\circ} = 18^{\circ}\) However, none of the options provided matches the calculated angle of minimum deviation. There might be a mistake in the question or options provided. The correct answer should be around \(18^{\circ}\).