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HO-ED-INT-06S Michelson Interferometer Sodium D’ Lines

$3,850.00

Michelson Interferometer

Sodium D’ Lines

In this model of Michelson interferometer, sodium vapor lamp is used as light source. Sodium has two emission wavelengths that have extremely close values and without sensitive equipment, it cannot be distinguished. Measurement of these lines, designated as D1 and D2 Fraunhofer lines, the average wavelength as well as difference between the two emission lines of sodium can be determined. The purpose of this experiment is to measure the wavelength of Sodium D emission lines.

The two beams of a Michelson interferometer interfere constructively when the waves add in phase and destructively when they add out of phase, producing circular interference fringes as a result. From this we can calculate wavelength of sodium source. The interference pattern observed with the sodium lamp contains two sets of fringes which disappear when the bright bands of one set are superimposed on the dark bands of the other. The wavelength separation of the Na D-line doublet is easily determined by observing the successive coincidence and discordance of the two sets of fringe systems produced by the doublet of wavelengths (λ1 and λ2 with λ1 > λ2 ). As D is increased, the two systems gradually separate and the maximum discordance occurs when the rings of one system are set exactly halfway between those of the other system. The discordance positions are most clearly seen as minima in the contrast of the pattern.


Experiment

   To find out the difference in wavelength of D1 and D2 lines of sodium light

Wavelength separation  λ1 - λ2  =  λ2 / 2D

where λ is the average wavelength of the sodium and D is the change in position of the micrometer for two successive discordance / coincidence.

   To determine the wavelength of monochromatic light

The wavelength of laser is calculated by;

λ  =  (2d / N) Δ

where ‘d’ is the change in position that occurs for ‘N’ fringes to pass and Δ is the calibration constant of the micrometer

  To measure refractive index of transparent materials

The light passes through a greater length of glass as the plate is rotated. The change in the path length of the light beam as the glass plate is rotated and relates the change in path length with the laser beam through air.

The refractive index of glass slide,

N  =  (2t - Nλ)  (1- cos θ)  /  2t (1-cos θ)  -  Nλ

Where t is the thickness of the glass slide, N is the number of fringes counted, λ is the wave length of light used and θ is the angle turned for N fringes.

Features:

    Sodium vapor lamp and diode laser is used
    CCD camera is used
    Computer interfaced
    Mirrors and beamsplitter are mounted on precision kinematic mounts for fine tuning and alignment

Drawings:

Related Topics:

  Interference of light
    Refractive index
    Wavelength
    D1 and D2 Fraunhofer lines

 

Scope of Delivery:

Optical Breadboard with Support
Kinematic Laser Mount
Beamsplitter Mount
Mirror Mount with Translation
Mirror Mount with Precision Translation
Rotation Stage
Camera lens Assembly Mount
Camera lens Assembly
Diffuser plate with Mount
Beamsplitter
Mirror with Cell
Glass Slide
Diode Laser with Power supply (Red)
Sodium vapor lamp with Power Supply
CCD Camera
Accessories

Thumb Screws
Allen keys
Dust Protective Cover
Instruction Manual
Net book (Optional)