Your friend, who is not in a physics course, is looking at your notes over the single-slitinterference experiment and asks:Why does the vertical slit produce a horizontal interference fringe? Why does thehorizontal slit produce a vertical interference fringe? Is this magic?How would you answer this question? Use the concepts we have been working with in physicsup to this point to explain your answer.

The phenomenon of interference occurs when two or more waves overlap with each other. In the case of…

Answered: Your friend, who is not in a physics…

Similar questions

How is the interference pattern created by eight evenly spaced slits of equal width different from the interference pattern created by two slits of with the same spacing and width that the eight slits have? O The bright fringes will be spaced farther apart in the two slit pattern. O All of these are true. There will be dim fringes between each pair of bright fringes for the eight slit pattern. The bright fringes are narrower for the two slit pattern.
Consider the following relative intensity graph for a double-slit experiment. The wavelength of the light used was λ = 633 nm. 1 0.8 0.6 0.4 0.2 0 0 (radians) Determine the width of the slits and the distance between the slits. Clearly indicate which features of the graph you are using to make your determination. You may have already noticed that the maxima are (approximately) 0.01 radians apart. except that there are no maxima at 8 = 0.05 radians or = 0.10 radians. How can you account for these "missing" maxima? (Hint: Consider how the relative intensity graph would be different if the width of the slits were decreased.)
Establish the relevant theoretical model: Write an equation linking the distance between the two slits (d), the wavelength of the light source (2), the distance from the screen (L), the linear position (y) of the bright interference bangs and the order of these bangs (m). Use the small-angle approximation. Isolate, in this relationship, the linear position of the bright fringes. Draw a graph of y as a function of m.
Consider a two-slit experiment in which the slit separation is 2.4 x 10-5 m and the interference pattern is observed on a screen that is 1.50 m away from the slits. The wavelength of light passing through the slits is 420 nm. What is the position of the second dark fringe? Show your calculations
Light with a wavelength is 600 nm passes through a slit and makes the intensity pattern shown in the figure on a screen that is 2.5 m from the slit. Based on this pattern, is the aperture a single slit or a double slit? Explain. If the aperture is a single slit what is the width? If it is a double slit, what is the spacing between the slits.
Monochromatic light illuminates a single slit with a width of 3.0 microns and produces a first-order diffraction minima at 17.5 degrees. What is the wavelength of the light? Show the algebraic form of the equation(s) that you apply and report your answer with correct units and number of significant figures.
ANSWER #2 A-C from the image provided
Question 1: Solve the following question, showing all of your steps and equation used. Assume that you create two slits that are 0.02 mm apart, and you place a viewing screen 1 meter away. You shine a laser beam of wavelength A = 540 nm on the two slits. a. What is the angle of the brightest fringe? b. What is the angle of the first order interference fringe? c. What is the angle where you will see the third order bright fringe? How far above the center of the source do you expect to see this fringe?
The light intensity vs. position graph of a double-slit experiment is shown below. The graph was made with helium-neon laser light of wavelength 640 nm shined through two very narrow slits separated by a small distance. The slits were 2.0 meters away from the probe. What is the spacing between the two slits, in mm? Your answer needs to have 2 significant figures, including the negative sign in your answer if needed. Do not include the positive sign if the answer is positive. No unit is needed in your answer, it is already given in the question statement. Light level allian Position of probe (mm)
What would you observe if you made the slit separation very very large (assuming you still had a coherent source that could still pass through both slits). Comment on how this is different from the single slit experiment.
Both parts plz
A student acquired a thin filter that transmits only half the incoming intensity, and he puts this filter in front of one of the slits in a double-slit experiment. What will happen to the fringes on the screen? The answer is that bright fringes become darker and dark fringes become brighter. Please explain why, in a way that someone who knows little physics would understand. Thank you!