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A)1.4102J0 oraction grating has a slit separation of 4 x 10-6 m. Find the wavelength of...
A multiple-slit diffraction grating has a slit separation of 1.50 × 10−6 m. Find the wavelength of the monochromatic light that will have its second-order bright fringe diffracted through an angle of 44.0°. (1 nm = 10−9 m) 425 nm 521 nm 13 nm 347 nm 260 nm
16. A Young's double slit has a slit separation of 2.50 x 10 m on which a monochromatic light beam is directed. The resultant bright fringes on a screen 1.00 m from the double slit are separated by 2.30 x 10 m. What is the wavelength of this beam?(1 nm-10 m) a. 373 nm b, 454 nm 575 nm d. 667 nm 17. What is the minimum thickness of a glycerin film (n 1.47) on which light of wavelength 600...
Please explain why the answer is 0.588 m. A double slit with a slit separation distance of 2.00 times 10^-5 m is illuminated by light of wavelength 560 nm. If the distance from the slits to the screen is 6.00 m, what is the separation distance between the center of the central bright fringe and the fourth dark fringe above it? Feel free to use the small-angle approximation.
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...
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.
Q. 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.
Q. 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.