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

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?

2-) A diffraction/interference pattern using a red helium-neon laser as a light source is observed on...

2-) A diffraction/interference pattern using a red helium-neon laser as a light source is observed on a screen a distance of 1.20 m from the element(s) producing the pattern. Using positive values to indicate distances to the right of the center of the pattern on the observing screen and negative values for distances to the left of the center, the following data is taken : Maxima(Cm) Minima(cm) -6.60 -6.10 -5.40 -4.75 -4.30 -3.60 -3.00 -2.35 -1.80 -1.20 +1.70 +1.15 +3.00...

A green laser beam (550 nm) strikes a grating and creates an interference pattern on a...

A green laser beam (550 nm) strikes a grating and creates an interference pattern on a wall 2.0 m away. The first maximum (fringe #1) occurs 11.0 cm from the middle of the central maximum. (a) Determine the distance between successive slits and the number of slits per mm. (b) Now a red laser (630 nm) replaces the green. On which side of the green fringe will the first red fringe appear – closer to the central maximum or further...

A diffraction grating with spacing d = 2000 nm produces an interference pattern on a screen...

A diffraction grating with spacing d = 2000 nm produces an interference pattern on a screen at a distance of 32 cm. If the first and second maxima produced are located at y = 3 cm, and 5 cm respectively, what is the wavelength of the light? Is this light visible? What does that say about the screen in this apparatus? If the frequency of the light used in question 1 above is decreased, will the positions of the maxima...

λ (nm) 633 L (mm) 180mm h0 (mm) 100mm h1 (mm) 200mm ϴ0 (°) 29.1° ϴ1...

λ (nm) 633 L (mm) 180mm h0 (mm) 100mm h1 (mm) 200mm ϴ0 (°) 29.1° ϴ1 (°) 48.01° d (mm) ? Calculated Line Density n (Lines/mm) ? Help me solve for question marks. Answer the questions using the data table as a reference 1. How similar is the CD’s groove number in Data Table 3 to the typical value of 625? What factors would affect any discrepancies? 2. How do the interference patterns produced by a CD and diffraction grating...

Would a simple or complex interference pattern appear if, instead of laser light, it was white...

Would a simple or complex interference pattern appear if, instead of laser light, it was white light shining through the double-slit?

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.

Light is diffracted through a single slit. How would the diffraction pattern on the screen change...

Light is diffracted through a single slit. How would the diffraction pattern on the screen change if the slit were made narrower? Explain.

1.a) A diffraction pattern is produced on a viewing screen by using a single slit with...

1.a) A diffraction pattern is produced on a viewing screen by using a single slit with blue light. Which of the following is true? 1)Using red light will broaden the pattern; widening the slit will also broaden the pattern. 2)Using red light will narrow the pattern; widening the slit will broaden the pattern. 3)Using red light will broaden the pattern; widening the slit will narrow the pattern. 4)Using red light will narrow the pattern; widening the slit will also narrow...

Optics: Interference and Diffraction 1. Why do you think the colors (when light diffracts) appears in...

Optics: Interference and Diffraction 1. Why do you think the colors (when light diffracts) appears in different places at all? 2. Why do the colors appear specifically in the order they do? 3. What kind of shape must the diffraction gratings be to produce the diffraction in light? Explain. (answer is rectangular slit grating, but explain why it’s this shape)