Michelson Interferometers: As we saw in the previous example, interference is a spectacular way of measuring small distances (like the thickness of a soap bubble), since we are able to resolve distances of the order of the wavelength of the light (for instance, for yellow light, we are talking about 0.5 of a millionth of a meter, 500nm). This has therefore technological applications. In the Michelson interferometer, light from a source (at the left, in the picture) hits a semi- plated mirror. Half of it goes through to the right and half goes upwards. The two halves are bounced back towards the half plated mirror, interfere, and the interference can be seen by the observer at the bottom. The observer will see light if the two distances travelled d 1 and d 2 are equal, and will see darkness if they differ by half a wavelength.
Lecture 26: TUE 27 APR 2010 Physics 2102 Jonathan Dowling Ch.
36: Diffraction EXAM III AVG = 60 STD = 15 A=10085 B=8475 C=7445
D=4440 F=390 Michelson Interferometers: As we saw in the previous
example, interference is a spectacular way of measuring small
distances (like the thickness of a soap bubble), since we are able
to resolve distances of the order of the wavelength of the light
(for instance, for yellow light, we are talking about 0.5 of a
millionth of a meter, 500nm). This has therefore technological
applications. In the Michelson interferometer, light from a source
(at the left, in the picture) hits a semi- plated mirror. Half of
it goes through to the right and half goes upwards. The two halves
are bounced back towards the half plated mirror, interfere, and the
interference can be seen by the observer at the bottom. The
observer will see light if the two distances travelled d 1 and d 2
are equal, and will see darkness if they differ by half a
wavelength. Michelson-Morley Experiment Michelson won the Nobel
prize in 1907, "for his optical precision instruments and the
spectroscopic and metrological investigations carried out with
their aid" "The interpretation of these results is that there is no
displacement of the interference bands.... The result of the
hypothesis of a stationary ether is thus shown to be incorrect."
(A. A. Michelson, Am. J. Sci, 122, 120 (1881)) The largest
Michelson interferometer in the world is in Livingston, LA, in LSU
owned land (it is operated by a project funded by the National
Science Foundation run by Caltech and MIT, and LSU collaborates in
the project).Mirrors are suspended with wires and will move
detecting ripples in the gravitational field due to astronomical
events. Gravitational Waves Interferometry: an International Dream
GEO600 (British-German) Hannover, Germany LIGO (USA) Hanford, WA
and Livingston, LA TAMA (Japan) Mitaka VIRGO (French-Italian)
Cascina, Italy AIGO (Australia), Wallingup Plain, 85km north of
Perth Things You Should Learn from This Lecture 1.When light passes
through a small slit, is spreads out and produces a diffraction
pattern, showing a principal peak with subsidiary maxima and minima
of decreasing intensity. The primary diffraction maximum is twice
as wide as the secondary maxima. 2.We can use Huygens Principle to
find the positions of the diffraction minima by subdividing the
aperture, giving min = p /a, p = 1, 2, 3, Calculating the complete
diffraction pattern takes more algebra, and gives I =I 0 [sin( )/ ]
2, where = a sin( )/. 4.To predict the interference pattern of a
multi-slit system, we must combine interference and diffraction
effects. Single Slit Diffraction When light goes through a narrow
slit, it spreads out to form a diffraction pattern. Analyzing
Single Slit Diffraction For an open slit of width a, subdivide the
opening into segments and imagine a Hyugen wavelet originating from
the center of each segment. The wavelets going forward ( =0) all
travel the same distance to the screen and interfere constructively
to produce the central maximum. Now consider the wavelets going at
an angle such that a sin a . The wavelet pair (1, 2) has a path
length difference r 12 =, and therefore will cancel. The same is
true of wavelet pairs (3,4), (5,6), etc. Moreover, if the aperture
is divided into p sub-parts, this procedure can be applied to each
sub-part. This procedure locates all of the dark fringes.
Conditions for Diffraction Minima Pairing and Interference Can the
same technique be used to find the maxima, by choosing pairs of
wavelets with path lengths that differ by ? No. Pair-wise
destructive interference works, but pair-wise constructive
interference does not necessarily lead to maximum constructive
interference. Below is an example demonstrating this. Calculating
the Diffraction Pattern We can represent the light through the
aperture as a chain of phasors that bends and curls as the phase
between adjacent phasors increases. is the angle between the first
and the last phasor. Calculating the Diffraction Pattern (2)
Diffraction Patterns = 633 nm a = 0.25 mm 0.5 mm 1 mm 2 mm
(radians) The wider the slit opening a, or the smaller the
wavelength, the narrower the diffraction pattern. Blowup X-band:
=10cm K-band: =2cm Ka-band: =1cm Laser: =1 m Radar: The Smaller The
Wavelength the Better The Targeting Resolution Angles of the
Secondary Maxima The diffraction minima are precisely at the angles
where sin = p /a and = p (so that sin =0). However, the diffraction
maxima are not quite at the angles where sin = (p+) /a and = (p+)
(so that |sin |=1). p (p+) /a Max = 633 nm a = 0.2 mm To find the
maxima, one must look near sin = (p+) /a, for places where the
slope of the diffraction pattern goes to zero, i.e., where d[(sin )
2 ]/d = 0. This is a transcendental equation that must be solved
numerically. The table gives the Max solutions. Note that Max (p+)
/a. (radians)
