What kind of a diffraction pattern would you expect from a grating? Briefly explain it and...

1) How would the interference pattern produced by a diffraction grating change if the laser light...

1) How would the interference pattern produced by a diffraction grating change if the laser light changed from red to blue? 2) How do the interference patterns produced by a CD and diffraction grating compare? Explain similarities, differences, and causes in your answer.

Suppose a certain wavelength of light falls on a diffraction grating and creates an interference pattern....

Suppose a certain wavelength of light falls on a diffraction grating and creates an interference pattern. (a) What happens to the interference pattern if the same light falls on a grating that has more lines per centimeter? (b) What happens to the interference pattern if a longer-wavelength light falls on the same grating?

Image a square aperture of width 149 \[Mu]m, 2775 mm away from a diffraction grating with...

Image a square aperture of width 149 \[Mu]m, 2775 mm away from a diffraction grating with a groove spacing of 1888 grooves/mm. You illuminate the diffraction grating by sending polychromatic light where the wavelengths are relatively close together and the average wavelength is 1037 nm through the square aperture onto the diffraction grating. What is the resolving power of the diffraction grating for second order light in this setup? (Assume the diffraction pattern is a Fraunhofer diffraction pattern.)

You have a diffraction grating with 3000 lines/cm. You also have a light source that emits...

You have a diffraction grating with 3000 lines/cm. You also have a light source that emits light at 2 different wavelengths, 428 nm and 707 nm, at the same time. The screen for your experiment is 1.5 meters from the diffraction grating. A. What is the line spacing for the grating? B. What is the difference in the angle of the 2nd bright fringe for each wavelength for this grating? C. Which wavelength is closer to the center of the...

24.73 . LIght is incident on a diffraction grating with 8600 lines/cm , and the pattern...

24.73 . LIght is incident on a diffraction grating with 8600 lines/cm , and the pattern is viewed on a screen 2.5 m from the grating. The incident light beam consists of two wavelengths, 4.5×10?7 m and 6.9×10?7 m . Part A Calculate the linear distance between the first-order bright fringes of these two wavelengths on the screen.

1a. For diffraction from a single slit, sketch the expected form of the diffraction pattern. 1b....

1a. For diffraction from a single slit, sketch the expected form of the diffraction pattern. 1b. In terms of the width of the slit, a, where would you expect to find the first minimum? As part of your answer consider points of the edge of the slit and in the middle of the slit, and the path difference between light waves originating at each point to a point on the screen that would result in destructive interference. Explain your answer.

Light from a Hydrogen lamp is focused through a diffraction grating with 770 lines/cm and the...

Light from a Hydrogen lamp is focused through a diffraction grating with 770 lines/cm and the diffraction pattern is shown on a screen that is 5.30 m away. You notice in the pattern that there are two distinct purple dots that are 16.46 cm and 17.70 cm from the central maximum, corresponding to the first-order maxima for two different wavelengths of light emitted by the lamp. What is the difference between the two wavelengths (in nm) corresponding to these purple...

The interference pattern on a screen 1.94 behind an 800 line/mm diffraction grating. The first maximum...

The interference pattern on a screen 1.94 behind an 800 line/mm diffraction grating. The first maximum is 69.7 cm away from the center. a. Find λ. b. How many bright fringes can we see? c. If you used small angle approximation to a.? Provide your answer as a percentage.

Q 3 What diffraction pattern would the octagonal aperture produce on the screen? Sketch the diffraction...

Q 3 What diffraction pattern would the octagonal aperture produce on the screen? Sketch the diffraction pattern in the space below and give reasons.

Q: You pass 589.0-nm radiation and 589.6-nmradiation through a diffraction grating that has525.0 slits/mm. Part A:...

Q: You pass 589.0-nm radiation and 589.6-nmradiation through a diffraction grating that has525.0 slits/mm. Part A: In the diffraction pattern, what is the angular separation between them = 3 peak for the 589.0-nm radiation and the m = 3 peak for the589.6-nm radiation? θ589.6nm−θ589.0nm= ? Part B: Are there fourth-order fringes in the diffraction pattern? yes?no?