Convex & Concave Lenses
Refraction Ray Diagrams
- Refraction occurs when light passes a boundary between two different transparent media
- At the boundary, the rays of light undergo a change in direction
- The direction is taken as the angle from a hypothetical line called the normal
- This line is perpendicular to the surface of the boundaries and is usually represented by a straight dashed or dotted line
- The change in direction depends on which media the light rays pass between:
- From less dense to more dense (e.g air to glass), light bends towards the normal
- From more dense to less dense (e.g. glass to air), light bends away from the normal
- When passing along the normal (perpendicular) the light does not bend at all
How to construct a ray diagram showing the refraction of light as it passes through a rectangular block
- The change in direction occurs due to the change in speed when travelling in different substances
- When light passes into a denser substance the rays will slow down, hence they bend towards the normal
- The only properties that change during refraction are speed and wavelength – the frequency of waves does not change
- Different frequencies account for different colours of light (red has a low frequency, whilst blue has a high frequency)
- When light refracts, it does not change colour (think of a pencil in a glass of water), therefore, the frequency does not change
Convex & Concave Lenses
- A lens is a piece of equipment that forms an image by refracting light
- There are two types of lens:
- Convex
- Concave
Convex Lenses
- In a convex lens, parallel rays of light are brought to a focus
- This point is called the principal focus
- This lens is sometimes referred to as a converging lens
- The distance from the lens to the principal focus is called the focal length
- This depends on how curved the lens is
- The more curved the lens, the shorter the focal length
- Convex lenses are commonly used in glasses to correct vision
- The lens act with the eye to make sure the rays are directed to a focal point behind the retina
- When the glasses are not there, the rays do not converge properly at a principal focus so the person cannot seen an image very well
The focal length is the distance from the lens to the principal focus
Concave Lenses
- In a concave lens, parallel rays of light are made to diverge (spread out) from a point
- This lens is sometimes referred to as a diverging lens
- The principal focus is now the point from which the rays appear to diverge from
- Concave lenses are commonly used in:
- Binoculars
- Telescopes
- Flashlights
- Cameras
- They primarily magnify an image
Parallel rays from a concave lens appear to come from the principal focus
Representing Lenses
- In diagrams, the following symbols are often used to represent each type of lens:
Concave and convex symbols
Worked example
The diagram below shows two parallel rays of light entering and passing through prism A and prism C.
Draw a third parallel ray entering and passing through prism B.
Step 1: Draw a parallel ray on the left
Step 2: Draw the refracted ray at the first surface
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- As the ray enters the block it bends towards the normal since it is going into a denser material
- In this case, the angle of refraction is smaller than the angle of incidence
Step 3: Draw the refracted ray at the second surface
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- As the ray leaves the block it bends away from the normal
- In this case, the angle of refraction is larger than the angle of incidence
Examiner Tip
Make sure you remember the symbol for each type of lens, as you will be expected to draw these for ray diagrams in your exam!
To remember which lens is converging or diverging, think of the following: Convex lens = Converging
