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Transcript
P5G Refraction Light waves change speed when they pass across the boundary between two substances with different densities, such as air and glass. This causes them to change direction and this effect is called refraction. Refraction follows a regular pattern. A ray of light travelling from air into glass has an angle of incidence that is usually greater than the angle of refraction. There is one special case you need to know. Refraction doesn't happen if the waves cross the boundary at an angle of 90° (called the normal) - in that case they carry straight on. Check your understanding of refraction by having a go at the animation. Refractive index Refraction happens at the boundary between two media (substances). This is because: when the wave speed decreases, the wave bends towards the normal when the wave speed increases, the wave bends away from the normal The diagram shows how this works for light passing into, and then out of, a Perspex block. The same would happen for a glass block. Refractive index The refractive index of a substance is a measure of the amount of bending after a boundary. It is calculated using this equation: refractive index = speed of light in a vacuum/speed of light in the medium The speed of light in a vacuum is 300 000 000 m/s (3 × 108 m/s). If the speed of light in glass is 200 000 000 m/s (2 × 108 m/s): refractive index = 300 000 000/200 000 00 = 1.5 The speed of light in air is close to its speed in a vacuum, so the refractive index of air is usually assumed to be 1. The refractive index of water is 1.33. (Note that refractive index has no units.) Dispersion When white light passes through a prism, it is dispersed and the different colours of the spectrum separate. Dispersion causes rainbows. You should be able to recall the spectral colours in order of wavelength: Remember: ROYGBIV or ‘Richard Of York Gave Battle In Vain’. Dispersion happens because the different spectral colours travel at the same speed in a vacuum, but at different speeds in a medium such as glass. The amount of bending increases as the change in wave speed increases. It also increases as the refractive index increases. For dispersion in a medium such as glass: each spectral colour has a different refractive index blue light has a greater refractive index in a given medium than red light blue light refracts (bends) more than red light Uses of Total Internal Reflection (TIR) Some, or all, of the light rays can be reflected when travelling from glass into air. Beyond a certain angle, called the critical angle, all the waves reflect back into the glass. We say that total internal reflection or TIR has happened. Have a go at the animation to check your understanding of this. know this law for the examination. The same thing happens for light rays travelling from water into air but different media have different critical angles. For example, the critical angle for glass is 42° but for water it is 49°. Using refractive index data: Light refracts towards the normal when it passes from a medium into another medium that has a higher refractive index - for example, from air (1) to glass (1.5). Light refracts away from the normal when it passes from a medium into another medium that has a lower refractive index - for example, from glass (1.5) to air (1). There are many uses of total internal reflection, including: optical fibres binoculars reflectors on road signs cat’s eyes on roads 3200000000000000000000000The higher the refractive index of a medium the lower its critical angle: Using speed of light data: Light refracts towards the normal when it passes into a medium where it travels more slowly. Light refracts away from the normal when it passes into a medium where it travels more quickly. Rearranging the equation for refractive index You should be able to rearrange this equation: refractive index = speed of light in a vacuum/speed of light in the medium Total internal reflection happens when the angle of incidence is greater than the critical angle. Predicting the direction of refraction You should be able to use refractive index data and the speed of light to predict the direction of refraction. This is described by Snell’s Law - but you do not need to For example, what is the speed of light in glass, assuming that the refractive index of glass is 1.5 and the speed of light in a vacuum is 3 × 108 m/s? = 2 x 108 m/s
