4oonin Problem #3. A light of wave length 400. Nm falls on a DIFFRACTION GRATING having...
4oonn Problem #3. A light of wave length 400 Nm falls on a DIFFRACTION GRATING having 7500 line /cm. A scree 2.3 m away from the diffraction grating is placed and the interference pattern was observed. A. How high up from the central; line is the first bright (maximum spot)? B. What is the MAXIMUM ORDER can be seen in this case? Screen 2.3m
QUESTION 7 Light of 430 nm passing through a diffraction grating with a separation, d=1.5 x 10-6 m creates an interference pattern on a screen 2.3 m away. What is the maximum number of bright fringes possible to see on the screen? A. Three OB. Seven C. Four O D. Six O E. Five QUESTIONS Light passing through a diffraction grating with a separation, d = 1.8 x 10m creates an interference pattern on a screen 1.2 m away. If...
495 nm laser light falls on a diffraction grating and forms an interference pattern on a wall 0.98 m behind the grating. The third bright spot is 1088 mm from the central bright spot. a) What is the spacing between the lines in the grating? d = μm b) How many lines per mm is this? lines/mm = c) If the grating were illuminated instead with a red 625 nm laser, what would be the distances to the first five...
Consider light with a wavelength of 519 nm is passing through a diffraction grating with 1208 lines per cm. At what distance from the central bright maximum will the 1st order maximum be seen on a screen placed 1.20 m from the diffraction grating. Give your answer in centimeters (cm) with 3 significant figures please. :)
2. Light of wavelength 545 nm passes through a diffraction grating with 1.35 x103 slits/cm The diffraction pattern is observed on a screen 1.70 cm from the grating. a) Determine the separation distance between the adjacent maxima on the screen. b) A second monochromatic light illuminates the diffraction grating simultancously. The second-order maximum of the second light falls midway between the central maximum and the first-order maximum for the first light on the screen. Determine the wavelength of the second...
A thin beam of laser light of wavelength 514 nm passes through a diffraction grating having 3952 lines/cm. The resulting pattern is viewed on a distant curved screen that can show all bright fringes up to and including ?90.0? from the central spot. If the experiment were performed with all of the apparatus under water (which has an index of refraction of 1.33), what would be the TOTAL number of bright spots that would show up on the screen?
If a diffraction grating produces a third-order bright spot for red light of wavelength 700 nm, at 65° from the central maximum at what angle will the second order bright spot be for violet light of wavelength 400 nm? How many lines per mm on this grating? If a diffraction grating produces a third-order bright spot for red light of wavelength 700 nm, at 65° from the central maximum at what angle will the second order bright spot be for...
Question 3: Light of wavelength 500 nm falls upon a diffraction grating with 800 lines/mm. a) Find the angle for the second order maximum and b) the distance between this second order and the central maximum on a screen 2.0 m away
White light containing wavelengths from 400 nm to 750 nm falls on a grating with 7500 lines/cm. How wide is the first-order spectrum on a screen 2.20 m away? ___m
Light with wavelength 500 nm passes through a diffraction grating with a spacing of 1 μm between adjacent openings in the grating. The light is projected on a screen 2 m away. At what angle is the first point of constructive interference observed, not counting the central maximum? A) 0.52 radians B) 1.57 radians C) 0.64 radians D) 0.50 radians