Refraction of light
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Transcript of Refraction of light
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PHYSICS Refraction Of Light
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Refraction Of Light• When a ray of light , travelling through one medium
strikes obliquely the surface of an other transparent medium, then there is change in its direction in the second medium. This change is called Refraction of light.
• Light refracts at boundary( b/w two mediums ) because of change in its speed.
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Refraction Of Light• If ray of light enters from rare into denser medium it
bends towards the normal. But when enters from denser into rare medium, it bends away from the normal.
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airglass
• e.g. from air to glass
• Light is bent towards the normal.
incident raynormal
refracted ray
From a less dense to a denser medium
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airwater
From a denser to a less dense medium• e.g. from water to air
• Light is bent away from the normal.
incident rayrefracted ray
normal
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airglass
Useful words to describe refraction of light
normal
incident ray
angle of refraction
angle of incidence
refracted ray
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Laws Of Refraction Of Light Incident ray, refracted ray and normal lie in the same
plane. The ratio of sine of angle of incident to the sine of
angle of refraction is constant in any two transparent mediums, which is termed refractive index (n).
Refractive index (n) =sin Li/Sin Lr = Constant
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Angle of Incidence (degrees) Angle of Refraction (degrees)
0.00 0.00
5.00 3.8
10.0 7.5
15.0 11.2
20.0 14.9
25.0 18.5
30.0 22.1
35.0 25.5
40.0 28.9
45.0 32.1
50.0 35.2
55.0 38.0
60.0 40.6
65.0 43.0
70.0 45.0
75.0 46.6
80.0 47.8
85.0 48.5
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Refraction of light
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Refractive index and speed of light distance that light travel in 1 s
distance that light travel in 1 svacuum (or air)
3 108 m
water (n = 1.33)2.25 108 m
glass (n = 1.5)2 108 m
diamond (n = 2.42)1.25 108 m
diamond (n = 2.42)1.25 108 m
Refractive index
Speed of light
fastestfastest
slowestslowest
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Refractive Index (n) Of Different Materials
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Prism• It is transparent body (Glass) ,
commonly having three sides rectangular and two sides triangular.
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Refraction Of Light Through Prism• Incident ray PQ strikes side AB of prism. Inside
prism the ray in shape of refracted ray QR, bends towards the normal XY . Then emergent ray RS coming from prism bends away from the normal LM.
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Refractive Index Of Glass Prism (nG)
• (nG)=
Sin (A + Dm)
2
Sin A
2
LA = Angle of prism.
LDm = Angle of minimum deviation.
nG = Refractive index of glass prism
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Refraction of light through prism
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Total Internal Reflection If ray of light passes from a denser medium(
water ) into a rare medium (air ) then it bends away from the normal.
Now increasing the angle of incidence, angle of refraction also increases.
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Total Internal Reflection At certain stage the angle of incidence has increased
so much that the corresponding value of angle of refraction becomes equal to 90o and refracted ray lies on the surface of denser medium.
The angle of incidence for which the angle of refraction is 90o is called the critical angle.
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Total Internal Reflection Now if the value of angle of incidence is increased
so much that it becomes greater than critical angle, then there is no more refraction but whole of it is reflected back in the denser medium.
Such reflection of light is called total internal reflection.
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Optical Fibres
• These are very thin, flexible glass rods, used for carrying light by total internal reflection from one end to other end. A bundle of optical fibres is called light pipe.
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Optical Fibres• The glass cladding of slightly lower refractive index
than that of the core, prevents surface damage to the core fibre, otherwise would allow light to escape.
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Optical Fibres (uses)
• Big advantage of an optical fibre is its small size and weight.
• Optical fibres are successfully used in internal surgery to examine body cavities and in telecommunication.
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Lens & Its KindsLENS = It is a transparent body(glass),
bounded by one or two Curve surfaces.KINDS OF LENS = there are two kinds of lens
(a) Convex Lens & (b) Concave Lens
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Convex Lens
It is thickest in the centre, because its boundaries are curving outwards.
As it bends light inwards( rays come together), hence it is also called Converging lens.
Its focal length is taken +ve. It forms real image.
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Double convex lens behaves like two prisms with attached bases.
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Concave Lens
It is thinnest in the centre, because its boundaries are curving inwards.
As it spreads light out( rays move apart), hence it is also called a diverging lens.
Its focal length is taken –ve. It forms virtual image.
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Uses Of Lenses
Convex lens is used in camera,projectors,binocular,telescope,microscope,spectacle and as magnifier etc.
Concave lens is used in spectacle for removing eye defect.
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Convex Lens Used As Magnifier
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Astronomical Telescope
Camera Compound microscope
Spectacle
Binocular
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Film Projector
Slide Projector
Over Head Projector
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Images Formed By Convex Lens
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Images Formed By Convex Lens
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Magnification & Sign Conventions For Lenses
Optical magnification is the ratio between the size of image & size of object.
M = hi = q
ho p
M = Magnification, hi = Height of image , ho = Height of object.
Distance b/w concave lens & image (q ) is taken - ve. Distance b/w convex lens & image( q ) is taken + ve. Focal length of concave lens ( f ) is taken - ve. Focal length of convex lens( f ) is taken + ve .
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Power Of Lens Power of lens is the reciprocal of the focal length
expressed in meters. Power = 1 Or P = 1 focal length (in m ) f The unit of refractive power of a lens is the
diopter( where 1 diopter = !/meter ). Converging lens has a positive power and diverging
lens has a negative power. One diopter is the power of lens of focal length one
meter. A Powerful lens deviates light rays more and thus
has a short focal length. Magnifying glass( of f=2cm) has power
diopters,while high power microscope objective(of f= 4mm) has power 250 diopters.
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Human EyeIn eye image is formed on retina.In it amount of light entering into eye is
controlled by Iris.For correct and clear image ( of near or
far objects) the thickness of eye’s lens is increased or decreased by ciliary muscles.
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Structure Of Human Eye
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Short- Sightedness(Myopia)
Definition = In this defect of vision an eye can see clearly only near objects,
Reason = the lens of eye becomes too much convergent, or eye ball becomes too long. So the images of distant objects is formed in front of the Retina.
Remedy = For correcting this defect concave lens ( diverging lens) of suitable focal length is used.
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Long- Sightedness (Hyperopia )
Definition =In this defect of vision, an eye can see clear only distant objects.
Reason = the lens of eye becomes less convergent or eye ball becomes too short.
Remedy = for removing this defect convex lens(converging lens) of suitable focal length is used.
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Contact Lens
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Astronomical Telescope It is used to see far objects near and clear In it the focal length of object lens is long and focal
length of eye piece is short. Objective lens forms real inverted image before eye
piece, which forms its magnified ,virtual image
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Astronomical Telescope
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Enlarged – Image is larger than actual object.Reduced –Image is smaller than object
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Compound Microscope
It is used to see minute near object clear and magnified.
In it the focal length of objective lens is short and focal length of eye piece is long.
Objective lens forms, enlarged ,inverted image, eye piece forms its further enlarged, virtual image.
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Compound Microscope
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CameraIn it image is formed on sensitive
film.Light reaching the film is
controlled by shutter and also by diaphragm.
For getting correct and clear image, convex lens is moved forward or backward.
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Slide Projector
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Lens Equation ( Convex Lens )
[As BD= p,DF= f & DI = q.]
As Δ OID and Δ ABD are similar
AB/OI = BD/DI……………….(I)
AS Δ CDF and Δ OIF are similar
CD/OI = DF/IF
As CD = AB
Then AB/OI = DF/IF ……………(II)
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Lens Equation ( Convex Lens )
[As BD= p,DF= f & DI = q.] As Δ OID and Δ ABD are similar AB/OI = BD/DI……………….(I) AS Δ CDF and Δ OIF are similar CD/OI = DF/IF As CD = AB Then AB/OI = DF/IF ……………(II)
comparing I and II we get. BD/DI = DF/IF or BD/DI = DF/DI –DF……………….(III) Put value of BD,DF and DI in equation III we get p/q =f/q-f B.C.M we get pq- pf = qf or pq=qf+ pf. Dividing both sides of above Equation by pqf we get pq/pqf = qf/pqf + pf/pqf 1/f = 1/p + 1/q (Lens Equation)
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