Imagine we have two slits with a spacing of 25 μm set up a distance of 2.5 m from a screen. We illuminate these slits with a bunch of different colors of light.
(a) Find the position on the screen where the UV light (λ “ 100 nm) maximum first lines up with a blue light (λ “ 400 nm) maximum.
(b) What are the values of m for each of these cases. Make sure to distinguish your m for the UV and blue light.
Imagine we have two slits with a spacing of 25 μm set up a distance of...
Two very narrow slits are spaced 1.85 μm and are placed 30.0 cm from a screen. What is the distance between the first and second dark lines of the interference pattern when the slits are illuminated with coherent light with a wavelength of 546 nm ? (Hint: The angle θ in equation dsinθ=(m+12)λ is not small.)
shows the fringes observed in a double-slit interference experiment when the two slits are illuminated by white light. The central maximum is white because all of the colors overlap. This is not true for the other fringes. The m = 1 fringe clearly shows bands of color, with red appearing farther from the center of the pattern, and blue closer. If the slits that create this pattern are 25 μm apart and are located 0.95 m from the screen, what...
If the distance between two slits is 1.5 µm and the distance to a screen is 1.5 m, find the angular spacing between the first-order bright fringes for light of 632 nm and 659 nm wavelength.
Two slits separated by a distance of d = 0.175 mm are located at a distance of D = 2.01 m from a screen. The screen is oriented parallel to the plane of the slits. The slits are illuminated by a monochromatic and coherent light source with a wavelength of λ = 604 nm. A wave from each slit propagates to the screen. The interference pattern shows a peak at the center of the screen (m=0) and then alternating minima...
A set of narrow vertical slits is located a distance D from a screen. The slits are equally spaced and have the same width. The intensity pattern in the figure is observed when light from a laser passes through the slits, illuminating them uniformly. The screen is perpendicular to the direction of the light. Data: Distance to the screen = 3.13 m, wavelength of Tight = 470 nm, Distance between tick marks on the intensity figure = 1.40 cm What...
A 2-slit arrangement with 60.3 μm separation between the slits is illuminated with 508 nm light. Assuming that a viewing screen is located 2.14 m from the slits, find the distance from the first dark fringe on one side of the central maximum to the second dark fringe on the other side. a. 72.1 mm b. 25.4 mm c. 36.1 mm d. 54.1 mm
I. Two slits separated by 0.050 mm are illuminated with green light ( 540 nm). The distance between the double slits and the screen is 1.0 m. How many bands of bright lines are there between the central maximum (0) and the 12-cm position (y 12cm)?
In a Young's double slit experiment, if the separation between the two slits is 0.050 mm and the distance from the slits to a screen is 2.5 m, find the spacing between the first-order and second-order bright fringes for light with wavelength of 600 nm. Correct answer is 3cm but I'm not sure how. Can somebody show all work to get this step? Thank you so much.
Monochromatic light (λ 470 nm) passes through two slits and onto a screen 3.0 m away. (a) If two nearby bright fringes are separated by 16 mm, what is the slit spacing? (b) If the slit spacing is reduced by a factor of two, what is the new distance between bright fringes?
For a particular double-slit experiment, the slit separation is 4.50 μm, the screen is located 4.00 m from the slits, and the wavelength of the light illuminating the slits is 580 nm (yellow). You have a detector located on the screen at a distance of 20.5 cm from the center of the interference pattern. (a) Where in the pattern is this point located – at a minimum, maximum or in-between? Give the m values associated with this position (e.g. at...