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Michelson interfrometer

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kamal abd el-kader

michelson interferometer and its uses

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Michelson interfrometer Prof. kamal abd El-kader Physics department, faculty of science, suez canal university Ismailia Egypt. kamalmarei@yahoo.com
Interference is the phenomenon in which two waves have the same direction, wavelength, amplitude, state of polarization and path difference constant with time combined to form bright and dark fringes Classification of interference Division wave front The wave front originating from a common source is divided into two parts by using two slits and the two wave fronts thus separated travels and finally brought together to produce interference. Such as fresenels biprism Division amplitude The amplitude of the incoming beam is divided into two parts either by partial reflection or refraction. These two parts travel in different paths and finally brought together to produce interference. Such as Michelson interferometer
Michelson interferomerter used to • Determine the wavelength of monochromatic source. • Determine the difference between two wavelengths of sodium light. • Determine the refractive index of gas
He-Ne beam from the source falls on the beam splitter. It splits into two perpendicular beams one to mirror M1 and the other to M2. The two beams are then reflected back along their original path by two separate mirrors M1 and M2 which are located at different distances from the beam splitter. The two beams interfere and produces interference fringes as shown in fig. 1 Whether the interference will be constructive or destructive depends on the relative phase of each of the combining light beams. This is determined by the path difference, 2d. With constructive interference, the wave amplitudes add in such a way to produce a maximum intensity beam striking the screen. The condition for maximum constructive interference is Determination the wavelength of monochromatic source.
Fig.1
𝟐𝝁𝒅 𝐜𝐨𝐬 𝜽 = 𝒏 Where µ is the refractive index of the medium for air=1 n is an integer ,  is the wavelength used. When the path length difference is an integer multiple of the wavelength, the recombining light beams will be in phase since both light beams originated from the same source. The resulting amplitude of the combined beam is then the sum of the amplitudes of each beam. With destructive interference, the phases of the light beams are such that the recombining beams cancel each other out. The condition for maximum destructive interference is 𝟐𝝁𝒅 𝒄𝒐𝒔 𝜽 = 𝟐𝒏 + 𝟏 𝟐 
When the path length is an odd half integer multiple of the wavelength, the recombining light beams will be exactly out of phase. The resulting amplitude of the combined beam will be the difference of the amplitudes of each beam. Moreover, since the amplitudes of the split beams are equal, the combined light beam will have zero amplitude. By moving one of the mirrors, we can change the path length difference As the path length difference changes, we would see both constructive and destructive interference. Draw the relation between the number of fringe (n) and distance (d) straight line will be obtained the slope is equal /2. wavelength will be calculated.
To study the effect of heat on Michelson interferometer A source of heat in the form of a filament (Heater) was inserted in the passage of one of the two interfering beams as shown in fig. 1 Plates1-4 illustrate an example of the visualization of fringe shrinking and disappearance at the center. Five fringes crossed the field of view when the temperature increased from 12 C to 23 C , the first fringe disappeared at temperature 20 C followed by the remaining four fringes shrinking to the center and disappeared successively, the recorded time and temperature for fringe disappearance is given in table 1
Plates 1-4 shrinking fringe disappearing at the centre Plate 1 Plate 2 Plate 3 Plate 4
Disappearance temperature (C ) Disappearance time(t min) Fringe number 20 2.9 1 20.5 7.8 2 21.0 16.8 3 21.5 31.8 4 23 57.8 5 Table1
Switching off the thermal source, the disappeared interference started to reappear again. The temperature at which each fringe crossed the field of view and that at which each fringe reappeared were recorded . Plates 5-8 show an example for the recorded reappearance fringe and table 2 gives the recorded time and temperature Table 2 Reappearance temperature (C ) Reappearance time(t min) Fringe number 19.5 10 5 19.0 15 4 18.5 21 3 18.0 30 2 16.5 59 1
Plate 5 Plate 6 Plate 7 Plate 8 Plates 5-8 fringe reaappearing at the centre
Michelson interfrometer

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Michelson interfrometer

  • 1. Michelson interfrometer Prof. kamal abd El-kader Physics department, faculty of science, suez canal university Ismailia Egypt. kamalmarei@yahoo.com
  • 2. Interference is the phenomenon in which two waves have the same direction, wavelength, amplitude, state of polarization and path difference constant with time combined to form bright and dark fringes Classification of interference Division wave front The wave front originating from a common source is divided into two parts by using two slits and the two wave fronts thus separated travels and finally brought together to produce interference. Such as fresenels biprism Division amplitude The amplitude of the incoming beam is divided into two parts either by partial reflection or refraction. These two parts travel in different paths and finally brought together to produce interference. Such as Michelson interferometer
  • 3. Michelson interferomerter used to • Determine the wavelength of monochromatic source. • Determine the difference between two wavelengths of sodium light. • Determine the refractive index of gas
  • 4. He-Ne beam from the source falls on the beam splitter. It splits into two perpendicular beams one to mirror M1 and the other to M2. The two beams are then reflected back along their original path by two separate mirrors M1 and M2 which are located at different distances from the beam splitter. The two beams interfere and produces interference fringes as shown in fig. 1 Whether the interference will be constructive or destructive depends on the relative phase of each of the combining light beams. This is determined by the path difference, 2d. With constructive interference, the wave amplitudes add in such a way to produce a maximum intensity beam striking the screen. The condition for maximum constructive interference is Determination the wavelength of monochromatic source.
  • 6. 𝟐𝝁𝒅 𝐜𝐨𝐬 𝜽 = 𝒏 Where µ is the refractive index of the medium for air=1 n is an integer ,  is the wavelength used. When the path length difference is an integer multiple of the wavelength, the recombining light beams will be in phase since both light beams originated from the same source. The resulting amplitude of the combined beam is then the sum of the amplitudes of each beam. With destructive interference, the phases of the light beams are such that the recombining beams cancel each other out. The condition for maximum destructive interference is 𝟐𝝁𝒅 𝒄𝒐𝒔 𝜽 = 𝟐𝒏 + 𝟏 𝟐 
  • 7. When the path length is an odd half integer multiple of the wavelength, the recombining light beams will be exactly out of phase. The resulting amplitude of the combined beam will be the difference of the amplitudes of each beam. Moreover, since the amplitudes of the split beams are equal, the combined light beam will have zero amplitude. By moving one of the mirrors, we can change the path length difference As the path length difference changes, we would see both constructive and destructive interference. Draw the relation between the number of fringe (n) and distance (d) straight line will be obtained the slope is equal /2. wavelength will be calculated.
  • 8. To study the effect of heat on Michelson interferometer A source of heat in the form of a filament (Heater) was inserted in the passage of one of the two interfering beams as shown in fig. 1 Plates1-4 illustrate an example of the visualization of fringe shrinking and disappearance at the center. Five fringes crossed the field of view when the temperature increased from 12 C to 23 C , the first fringe disappeared at temperature 20 C followed by the remaining four fringes shrinking to the center and disappeared successively, the recorded time and temperature for fringe disappearance is given in table 1
  • 9. Plates 1-4 shrinking fringe disappearing at the centre Plate 1 Plate 2 Plate 3 Plate 4
  • 10. Disappearance temperature (C ) Disappearance time(t min) Fringe number 20 2.9 1 20.5 7.8 2 21.0 16.8 3 21.5 31.8 4 23 57.8 5 Table1
  • 11. Switching off the thermal source, the disappeared interference started to reappear again. The temperature at which each fringe crossed the field of view and that at which each fringe reappeared were recorded . Plates 5-8 show an example for the recorded reappearance fringe and table 2 gives the recorded time and temperature Table 2 Reappearance temperature (C ) Reappearance time(t min) Fringe number 19.5 10 5 19.0 15 4 18.5 21 3 18.0 30 2 16.5 59 1
  • 12. Plate 5 Plate 6 Plate 7 Plate 8 Plates 5-8 fringe reaappearing at the centre