Calculate the refractive index from speed of light or Snell's Law angles. Includes material comparison, Brewster angle, critical angle, and wavelength data.
The index of refraction (or refractive index), denoted n, is a dimensionless number that describes how fast light travels through a material relative to its speed in a vacuum. Defined as n = c/v, where c is the speed of light in vacuum and v is its speed in the medium, the refractive index is one of the most fundamental properties in optics and determines how light bends, reflects, and propagates through any transparent material.
Every optical design — from eyeglasses and camera lenses to fiber optics and laser systems — depends on accurate refractive index values. The refractive index also varies with wavelength (dispersion), which is why prisms split white light into a rainbow and why lenses suffer chromatic aberration. Materials range from n ≈ 1.0003 for air to n ≈ 4.0 for germanium in the infrared.
This calculator determines the refractive index from either the measured speed of light in a medium or from Snell's Law angle measurements. It then provides a comprehensive set of derived quantities including Brewster's angle, critical angle for total internal reflection, wavelength in the medium, and a full material comparison table to help identify the substance or select the right material for optical design.
Use this calculator to connect light speed, refraction angles, and derived optical properties such as critical angle and Brewster angle for a given material. It is a quick way to keep the measured inputs and the derived optical properties together when comparing materials or verifying a lab result. The same output also helps when you want a compact check of how strongly a medium bends light without reworking the Snell calculation by hand.
From speed: n = c / v, where c = 299,792,458 m/s. From Snell's Law: n₂ = n₁ · sin(θ₁) / sin(θ₂). Wavelength in medium: λ_m = λ_vacuum / n.
Result: n = 1.4990
If light travels at 200,000,000 m/s in a medium, its refractive index is 299,792,458 / 200,000,000 ≈ 1.4990, close to glass or glycerin.
Refractive index determines how quickly a phase front travels in a material and how strongly a ray bends when it crosses an interface. That one property influences lens power, reflection, total internal reflection, dispersion, and optical path length.
A refractive index quoted without wavelength is only part of the story. Optical glasses, liquids, and crystals usually have slightly different indices for different wavelengths, which is why prisms spread colors and why lens designers worry about chromatic aberration.
This calculator is useful for quick checks from measured speeds or Snell-law data, but material selection in real optics work often also depends on absorption, birefringence, thermal behavior, and coating design. The refractive index is necessary, not sufficient.
A higher refractive index means light travels slower in that material and bends more when entering it from a less dense medium. It also means stronger reflections at the surface.
For some materials at certain frequencies (e.g., X-rays in glass), the phase velocity can exceed c, giving n < 1. However, the group velocity (which carries information) remains below c.
This is called dispersion. It occurs because the material's electrons respond differently to different frequencies of light, altering the effective speed for each wavelength. That is why the same material can bend red and blue light by slightly different amounts.
Common methods include refractometers based on critical angle, prism deviation measurements, interferometry, and ellipsometry for thin films and coatings. The method chosen depends on the material form and the precision required.
Water has n ≈ 1.333 at 589 nm (sodium D-line). It increases slightly for shorter wavelengths and decreases slightly for longer wavelengths.
Yes. For most materials, increasing temperature slightly decreases the refractive index due to thermal expansion. The effect is small but measurable.