Objective:
The objective is to (a) verify the wave nature of light by measuring its wavelength in an interference phenomenon, (b) learn about diffraction grating, and (c) measure the wavelengths of red and violet colors.
Equipment:
A diffraction grating, a laser pointer of known wavelength, an optical bench, a target holder, an orthogonal skew clamp, a tape measure, a white light bulb (4060 watts) with a holder, a ruler, and a calculator
Theory:
Young’s DoubleSlit Experiment verifies that light is a wave simply because of the bright and dark fringes that appear on a screen. It is the constructive and destructive interference of light waves that cause such fringes.
Constructive Interference of Waves
The following two waves ( Fig. 1 ) that have the same wavelength and go to maximum and minimum together are called coherent waves. Coherent waves help each other’s effect, add constructively, and cause constructive interference. They form a bright fringe.
Destructive Interference of Waves
In Fig. 2 however, the situation is different. When wave with amplitude A_{1} is at its maximum, wave with amplitude A_{2} is at its minimum and they work against each other resulting in a wave with amplitude A_{2} – A_{1}. These two completely out of phase waves interfere destructively. If A2 = A1, they form a dark fringe.
The bright and dark fringes in the Young’s experiment follow the following formulas:
Bright Fringes: d sin(θ_{m}) = m λ where m = 0,1,2,3, ...
Dark Fringes: d sin(θ_{m}) = (m+1/2) λ where m = 0,1,2,3, ...
The above formulas are based on the following figures:
Check the following statement for correctness based on the above figure.
Light rays going to D_{2} from S_{1} and S_{2} are 3(½ λ) out of phase (same as being ½ λ out of phase) and therefore form a dark fringe.
Light rays going to B_{1} from S_{1} and S_{2} are 2(½ λ) out of phase (same as being in phase) and therefore form a bright fringe.
Note that SB_{o} is the centerline.
Going from a dark or bright fringe to its next fringe changes the distance difference by ½ λ.
Diffraction Grating:
Diffraction grating is a thin film of clear glass or plastic that has a large number of lines per (mm) drawn on it. A typical grating with a poor line density is (250 lines)/mm. Using more expensive laser techniques, it is possible to create line densities of (3000 lines)/mm or higher. When light from a bright and small source passes through a diffraction grating, it generates a large number of sources. The very thin space between every two adjacent lines of the grating becomes an independent source. These sources are coherent sources meaning that they emit in phase waves with the same wavelength. These sources act independently such that each source sends out waves in all directions. On a screen a distance (D) away, points can be found whose distance differences from these sources are different multiples of λ causing bright fringes. One difference between the interference of many slits (diffraction grating) and doubleslit (Young’s Experiment) is that the former makes principle maximums with smaller intensity maximums in between. The principal maximums (Maxima) occur on both sides of the central maximum at points (or angles) for which a formula similar to Young’s holds true.
D = the distance from the grating to the screen.
d = the spacing between every two lines (same thing as every two sources)
If there are (N) lines per mm of the grating, then (d), the space between every two adjacent lines or (every two adjacent sources) is
The diffraction grating formula for the principal maxima is:
d sin ( θ_{m}) = m λ where m = 1, 2, 3, ...
Procedure:
a) Fix a laser pointer and the diffraction grating (placed in a target holder) on an optical bench as shown. Try to make a distance (grating to wall) of about 1m.
a) Make sure that the direction of the optical bench is normal (at right angle) to the wall and that you are measuring the perpendicular distance (D) from the grating to the wall.
b) Measure Y1, Y2, and D with a precision of (mm), or tenth of a (cm), and record the values.
c) Angles θ_{1} and θ_{2} now can be calculated from the measured values as follows:
a) Use the ( tan^{1}) function (builtin in your calculator) to calculate θ_{1} and θ_{2}.
b) Use angles θ_{1} and θ_{2} along with the wavelength given on your laser pointer (in meter) and the formula for diffraction grating to calculate (d), the distance between adjacent spaces (sources) on the grating. Find (d) once for m=1 (by using θ_{1} ) and once for m=2 (by using θ_{2}). Theoretically, the two values you obtain for (d) must be equal; however, due to measurement errors, they might be slightly different. Find an average value for (d) in meter.
c) Determine the number of lines per mm of the grating from (d).
a) Hold a diffraction grating close to your eye and look at the objects around you.
You will see a continuous spectrum of rainbow colors around bright objects. The diffraction grating separates the colors of white light similar to what a prism does. White light coming from a bright object separates into its constituent colors as it passes thru the grating and reaches your eyes. If you are looking through a grating at a bright spot such as the filament of a lit light bulb, you will be able to direct another person to move to the left or right and mark the ends of the spectrum you are observing. By measuring the distance between each end of the spectrum and the bright filament (Y_{violet} or Y_{red}) and (D) the distance from the filament to the grating (held by you), it is possible to calculate the angles θ_{violet} and θ_{red}. Then by using the formula
d sin ( θ_{m }) = m λ
the corresponding wavelengths for violet and red light can be determined.
Note that through the grating you will see more than one rainbow band. You will see two or three bands on each side of the center. If you use the 1^{st} band to one side of the center, then m=1. For the 2^{nd} band m=2, and for the 3^{rd} band m=3.
b) Place the optical bench near the board in your lab or class on a somewhat high table.
c) Make sure that the optical bench stays at right angle to the board and mount a lightbulb so that it almost touches the board. Turn the light bulb on.
d) Fix a diffraction grating on a mounting rod that is tightened against the edge of a table. The mounting rod must hold the filament parallel to the board. Also when you look into the grating, your line of sight must be normal to the board and be in the same vertical plane that the optical bench or the filament of the line bulb is. If it is not make the necessary adjustments. A diagram of the setup is shown below:
V = The violet end of spectrum R = The red end of spectrum LV = Y _{violet} LR = Y _{red}


a) While looking into the grating and observing the spectrum, instruct your partner to the extreme ends of the spectrum so that he/she can mark those points. Your partner must have previously observed the same spectrum and have a good understanding of the experimental procedure.
b) When those points are marked, doublecheck their precision and measure distances LV and LR to the nearest cm as shown in the figure. Also measure D.
c) From the data collected, calculate angles θ_{violet} and θ_{red} and use each in the abovementioned formula separately to find the corresponding wavelengths.
Data:
Given:
λ_{laser} = As read from the laser pointer.
Measured:
Part A: Part B:
Y = Y_{violet} =
D = Y_{red} =
D =
Calculations:
To be performed by students
Comparison of the Results:
To be completed by students
Conclusion: To be explained by students
Discussion: To be explained by students