 Snell's law

/snelz/, Optics.the law that, for a ray incident on the interface of two media, the sine of the angle of incidence times the index of refraction of the first medium is equal to the sine of the angle of refraction times the index of refraction of the second medium.[named after Willebrod Snell van Royen (d. 1626), Dutch mathematician]
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Relationship between the path taken by a ray of light as it moves from one medium to another and the refractive indices of the two media.Discovered in 1621 by Willebrord Snell (1580–1626), the law went unpublished until its mention by Christiaan Huygens. If n_{1} and n_{2} represent the indices of refraction of two media, and θ_{1} and θ_{2} are the angles of incidence and refraction that a ray of light makes with the line perpendicular to the boundary (the normal), Snell's law states that n_{1}/n_{2} = sin θ_{2}/sin θ_{1}. Because the ratio n_{1}/n_{2} is a constant for any given wavelength of light, the ratio of the two sines is also a constant for any angle.* * *
▪ physicsin optics, a relationship between the path taken by a ray of light in crossing the boundary or surface of separation between two contacting substances and the refractive index (q.v.) of each. This law was discovered in 1621 by the Dutch astronomer and mathematician Willebrord van Roijen Snell (Snell, Willebrord van Roijen) (1580–1626; also called Snellius). The account of Snell's law went unpublished until its mention by Christiaan Huygens in his treatise on light.In the Figure—>, n_{1} and n_{2} represent the indices of refraction for the two media, and α_{1} and α_{2} are the angles of incidence and refraction that the ray R makes with the normal (perpendicular) line NN at the boundary. Snell's law asserts that n_{1}/n_{2} = sin α_{2}/sin α_{1}.Because the ratio n_{1}/n_{2} is a constant for any given wavelength of light, the ratio of the two sines is also a constant for any angle. Thus, the path of a light ray is bent toward the normal when the ray enters a substance with an index of refraction higher than the one from which it emerges; and because the path of a ray of light is reversible, the ray is bent away from the normal when bgtering a substance of lower refractive index.The reason light is refracted in going from one medium to another is shown in the Figure—>. According to Huygens' principle, each point on a wave front of light is a source of new wavelets. A parallel beam, consisting of the three rays R_{1}, R_{2}, and R_{3}, is incident on a boundary plane AF separating two media of indices n_{1} and n_{2}, and it has a plane wave front ABC. In this example, the speed of light is greater in the first medium than in the second (n_{1} is less than n_{2}). Consequently, according to Huygens' principle, the radius of the wavelets in the first medium is greater than the radius in the second. By the time a point C on the wave front ABC has moved from C to F on the plane, the point A of the wave front has moved a distance of only AD in the second medium. A plane DEF tangent to the new wavelets represents the new wave front, and lines perpendicular to it represent the paths taken by the rays in the second medium.* * *
Universalium. 2010.