The green line emitted from Mercury has a wavelength of ? = 5460.7 Å. Assuming that you have a diffraction grating with 5000 lines per centimeter, at what angle would you expect to find the primary diffraction maximum for this spectral line?
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The green line emitted from Mercury has a wavelength of ? = 5460.7 Å. Assuming that...
3. Diffraction Grating: Line measurement and calculation Line Element Number Color Mercury Blue 8.40 Wavelength Green 10.50 Orange 11.30 Attach a separate sheet with your calculations. Light source Observed line Grating Eye 4 Figure 9: Line Observed with Diffraction Grating DO NOT LOOK DIRECTLY AT THE LIGHT SOURCE. Use a meter stick to measure distances "a" and "x" in Figure 3. “x” is the distance from the emission tube (the source) to a line in the spectrum. One partner, the...
A diffraction grating with 155 slits per centimeter is used to measure the wavelengths emitted by hydrogen gas. At what angles in the third-order spectrum would you expect to find the two violet lines of wavelength 434 nm and of wavelength 410 nm? (angles in radians) The 434 nm line: [5 points] 2 attempt(s) made (maximum allowed for credit = 5) [after that, multiply credit by 0.5 up to 10 attempts] The 410 nm line:
A diffraction grating with 155 slits per centimeter is used to measure the wavelengths emitted by hydrogen gas. At what angles in the third-order spectrum would you expect to find the two violet lines of wavelength 434 nm and of wavelength 410 nm? (angles in radians) The 434 nm line: [5 points] 2 attempt(s) made (maximum allowed for credit = 5) [after that, multiply credit by 0.5 up to 10 attempts] The 410 nm line:
9. (10) A 600 lines/mm diffraction grating is used to look at the spectrum of a mercury vapor lamp. In second order, the blue spectral line of mercury is located at an angle of 31.5° from the central maximum. Find the wavelength of the blue mercury spectral line in nm units.
A diffraction grating has 2000 lines per centimeter. Randomized Variables i = 515 nm At what angle, in degrees, will the first-order maximum be for 515-nm wavelength green light?
The hydrogen spectrum has a red line at 656 nm and a violet line at 434 nm. What angular separation between these two spectral lines is obtained with a diffraction grating that has 4014 lines/cm? (Assume that the light is incident normally on the grating.) 5.11 x first order separation Your incorrect answer may have resulted from roundoff error. Make sure you keep extra significant figures in intermediate steps of your calculation. 10.21 x second order By how many wavelengths...
The light shining on a diffraction grating has a wavelength of 485 nm (in vacuum). The grating produces a second-order bright fringe whose position is defined by an angle of 8.09°. How many lines per centimeter does the grating have?
The light shining on a diffraction grating has a wavelength of 495 nm (in vacuum). The grating produces a second-order bright fringe whose position is defined by an angle of 9.34. How many lines per centimeter does the grating have?
The light shining on a diffraction grating has a wavelength of 481 nm (in vacuum). The grating produces a second-order bright fringe whose position is defined by an angle of 8.59°. How many lines per centimeter does the grating have?
(a) White light is spread out into its spectral components by a diffraction grating. If the grating has 2,070 grooves per centimeter, at what angle (in degrees) does red light of wavelength 640 nm appear in first order? (Assume that the light is incident normally on the gratings.) (b) What If? What is the angular separation (in degrees) between the first-order maximum for 640 nm red light and the first-order maximum for green light of wavelength 525 nm? 11. (-/1...