QUESTION 7 Light of 430 nm passing through a diffraction grating with a separation, d=1.5 x...
1. Monochromatic blue light of wavelength 440-nm passes through a 3300 lines/cm diffraction grating and the interference pattern is observed on a screen. (a) Determine the interference angle for the 2nd order bright fringe. (5 points) (b) If a screen is 0.75-m away, how far (in cm) is the 2nd order bright fringe from the center? Show all steps. [3 points) (c) Sketch the path taken by this light to reach the center, the 1st and 2nd order bright fringes....
1. Monochromatic blue light of wavelength 440-nm passes through a 3300 lines/cm diffraction grating and the interference pattern is observed on a screen. (a) Determine the interference angle for the 2nd order bright fringe. 15 points) (b) If a screen is 0.75-m away, how far (in cm) is the 2nd order bright fringe from the center? Show all steps. [3 points) (c) Sketch the path taken by this light to reach the center, the 1st and 2nd order bright fringes....
A green laser light ( = 532 ) passes through a diffraction grating (500 lines per millimeter) and creates interference patterns on a viewing screen 0.4 m away. What is the position of the 2nd-order bright fringe on the screen?
Light of wavelength 429 nm (in vacuum) is incident on a diffraction grating that has a slit separation of 1.2 × 10-5 m. The distance between the grating and the viewing screen is 0.10 m. A diffraction pattern is produced on the screen that consists of a central bright fringe and higher-order bright fringes (see the drawing). (a) Determine the distance y from the central bright fringe to the second-order bright fringe. (Hint: The diffraction angles are small enough that...
Light of wavelength 385 nm (in vacuum) is incident on a diffraction grating that has a slit separation of 1.2 × 10-5 m. The distance between the grating and the viewing screen is 0.18 m. A diffraction pattern is produced on the screen that consists of a central bright fringe and higher-order bright fringes (see the drawing). (a) Determine the distance y from the central bright fringe to the second-order bright fringe. (Hint: The diffraction angles are small enough that...
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. :)
Coherent light of wavelength 548 nm passes through two slits. In the resulting interference pattern on a screen 4.6 m away, adjacent bright fringes are 5.60 mm apart. What is the separation between the 2nd and the 3rd order maxima for light with a wavelength of 650 nm?
A diffraction grating has 3 x 106 lines per meter. The grating is illuminated by monochromatic plane waves of wavelength 600 nm at normal incidence that forms an interference pattern on a screen located 0.50 m away. a) Find the angle the first bright fringe. b) Find the angle corresponding to the second bright fringe. c) Find the angle of the third bright fringe.
A diffraction grating has 3 x 106 lines per meter. The grating is illuminated by monochromatic plane waves of wavelength 600 nm at normal incidence that forms an interference pattern on a screen located 0.50 m away. a) Find the angle the first bright fringe. b) Find the angle corresponding to the second bright fringe. c) Find the angle of the third bright fringe.
A diffraction grating has 3 x 106 lines per meter. The grating is illuminated by monochromatic plane waves of wavelength 600 nm at normal incidence that forms an interference pattern on a screen located 0.50 m away a) Find the angle the first bright fringe. b) Find the angle corresponding to the second bright fringe. c) Find the angle of the third bright fringe.