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P7: Waves, lenses and telescopes
Descripción
(P7) Physics Mapa Mental sobre P7: Waves, lenses and telescopes, creado por jamiemcparlin el 16/05/2013.
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P7: Waves, lenses and telescopes
Light and sound travel in waves. These waves can be:
Refracted
This is caused when waves cross a boundary between one medium and another
The frequency is the same but there is a change in wavelength
This leads to a change in wave speed
Which causes a change in wave direction
The colours that make up white light are refracted by different amounts as they pass through a prism
Red light is refracted the most
Violet light is refracted the least
This occurs because the colours that make up white light have different frequencies and wavelengths
Defracted
This is caused when waves move through a narrow gap or past an obstacle
Diffraction is most obvious when:
The size of the gap is smaller or the same size as the wavelength of the wave
The waves that pass obstacles have long wavelengths
Radiation is diffracted by the aperture of a telescope
to produce sharp images, the aperture must be a lot bigger than the wavelength of the radiation detected by the telescope
Convex/converging Lenses
These bend rays of light inwards as it passes through the lens
If the rays of light are parallel, the rays of light will be brought to focus at the focal point
This is due to refraction
The greater the curvature of the lens, the more powerful it will be
This means that of two lenses made of the same material, the one with the biggest curvature will be more powerful
You can calculate the power of the lens using a formula
Power (dioptres) = 1/ focal length
The focal length is the distance between the focal point and the lens
Telescopes
A simple refracting telescope is made from two converging lenses of different powers
The eye piece lens is more powerful than the objective lens
The objective lens captures parallel light from a different object and brings it to a point on the focal point of the lens
This point is also the focal point for the eyepiece lens. So the image acts as an object and the eyepiece lens magnifies it
the distance between the lenses will be equal to the focal lengths of the objective and eyepiece lenses added together
One type of telescope is an astronomical (reflecting) telescope
This uses a concave mirror instead of a convex mirror for the objective lens
This allows the telescope to be larger so it takes in more light
The larger the telescope, the more detail the image it produces has
Concave mirrors reflect rays of parallel light and bring them to focus
Angular magnification
The image of a disant magnified object will appear closer than the actual object is
So the angles made by ray lines entering the eye is greater
the increase in angle is called angular magnification and makes the object appear closer
You can calculate the angular magnification of a telescope using a formula
Magnification= Focal length of objective lens / focal length of eyepiece lens
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