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Newton’s Rings TIT GROUP Of INSTITUTIONS, BHOPAL [M.P.] By

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1 Newton’s Rings TIT GROUP Of INSTITUTIONS, BHOPAL [M.P.] By
Dr. Gyanendra Pandey Engg. Physics

2 Introduction Newton’s rings
Interference occurs between the light reflected from the lower surface of the lens and the upper surface of the glass plate G. Since the convex side of the lens is a spherical surface, the thickness of the air film will be constant over a circle (whose centre will be at O ) and we will obtain concentric dark and bright rings. Newton’s rings

3 Each ring will be locus of all such points where thickness is same.
It should be pointed out that in order to observe the fringes the microscope has to be focused on the Surface of the film. Each ring will be locus of all such points where thickness is same.

4 A B Plano convex lens Air film Q P O Glass plate Thickness of air film is zero at point of contact O.

5 Reflected light L Air film G Circular interference fringes are formed by reflected light

6 Microscope 45º S glass L Lens Air film Glass plate

7 Condition for bright ring will be
For air film ,  =1 and for near normal incidence r is very small and hence cos r = 1 Thus, Where n = 0,1,2,3….

8 For dark rings, Again for air film  = 1 and for small r we have Condition for dark rings,

9 O R R - tn A B tn tn M N rn

10 R = radius of curvature of lens
t = thickness of air film at a distance AB =rn OA = R - t From OAB R2 = (R – t)2+rn2 rn2 = R2 - (R – t)2 = R2 - R2 –t2 +2Rt = 2Rt – t2 As R>>t , rn2 = 2Rt  t = rn2/2R

11 So condition for bright rings 2t = (2n+1)/2

12 Similarly for dark rings,
Diameter of dark rings,

13 CENTER IS DARK At n = 0, radius of dark ring = 0. radius of bright ring = Alternately dark and bright rings will be produced. The spacing between second and third dark rings is smaller than the spacing between the first and second one.

14 Consider the diameter of dark rings
Four fringes

15 Fringe width decreases with the order of the
Fringe and fringes get closer with increase in their order.

16 Wavelength determination
Radius of the nth dark ring rn is given by Similarly for (n+m)th dark band

17 (2) – (1)

18 Suppose diameter of 6th and 16th ring are
Determined then, m = 16-6 = 10 So Radius of curvature can be accurately measured with the help of a spherometer and therefore by measuring the diameter of dark or bright ring you can experimentally determine the wavelength.

19

20 Newton’s rings with transmitted light

21

22 Transmitted light

23 Condition for bright fringes
Condition for dark fringes For air as thin film and near normal incidence  = 1 and cosr = 1 So for bright fringes, 2t = n For dark fringes,

24 But we know that , r = radius of ring For bright rings For dark rings

25 If we put n = 0 then r = 0 for the bright ring
So for Newton's rings for transmitted rays the central ring will be bright. CENTRAL RING IS BRIGHT.

26 WAVELENGTH DETERMINATION
We know radius of the nth dark ring rn is …….(1)

27 Similarly, ……..(2) (2) – (1) ……..(3)

28 Suppose diameter of the 8th and 18th ring are
Determined then, m = 18-8 =10 and

29 Refractive index determination
air Diameter of the dark rings

30 Liquid of refractive index 

31 (for near normal incidence and g<
Condition for dark ring formation …..(4)

32 Similarly we can get …….(5) (5) – (4) So, …….(6) This is the value of  if  is known.

33  Can also be determine if  is unknown
We have from equation (3) and (6) ……..(3) …….(6)

34 Divide Equation (3) by (6)

35 Thank You


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