A laser with wavelength 56.25 µm is shining light on a double slit with slitseparation 0.450 mm . This results in an interference pattern on a screen adistance L away from the slits. We wish to shine a second laser, with a differentwavelength, through the same slits such that the fourth minimum of the first laseris at the same location as the second maximum of the second laser.FigureH ———————G→FDBE-0||1 of 1CENTRAL MAXIMUMPart AIn the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown representsthe second maximum?► View Available Hint(s)Point APoint BPoint CPoint DPoint EPoint FPoint GPoint HSubmitPart BIn the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown representsthe fourth minimum?► View Available Hint(s)

Answered: Image /qna-images/answer/4e70f826-851a-4d13-8778-60ed0105c35c.jpg

A laser with wavelength 56.25 μm is shining light on a double slit with slit separation 0.450 mm. This results in an interference pattern on a screen a distance L away from the slits. We wish to shine a second laser, with different wavelength, through the same slits such that the fourth minimum of the first laser is at the same location as the second maximum of the second laser. Figure 1111! H F D B G→ E-> C- A 1 of 1 CENTRAL MAXIMUM Part A In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents the second maximum? ►View Available Hint(s) O Point A O Point B оооо 0 0 0 O Point C O Point D O Point E O Point F O Point G O Point H Submit Part B In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents the fourth minimum? ► View Available Hint(s)

A laser with wavelength 56.25 μm is shining light on a double slit with slit separation 0.450 mm. This results in an interference pattern on a screen a distance L away from the slits. We wish to shine a second laser, with different wavelength, through the same slits such that the fourth minimum of the first laser is at the same location as the second maximum of the second laser. Figure 1111! H F D B G→ E-> C- A 1 of 1 CENTRAL MAXIMUM Part A In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents the second maximum? ►View Available Hint(s) O Point A O Point B оооо 0 0 0 O Point C O Point D O Point E O Point F O Point G O Point H Submit Part B In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents the fourth minimum? ► View Available Hint(s)

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Question

A laser with wavelength 56.25 µm is shining light on a double slit with slit
separation 0.450 mm . This results in an interference pattern on a screen a
distance L away from the slits. We wish to shine a second laser, with a different
wavelength, through the same slits such that the fourth minimum of the first laser
is at the same location as the second maximum of the second laser.
Figure
H ———————
G→
F
D
B
E
-0
||
1 of 1
CENTRAL MAXIMUM
Part A
In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents
the second maximum?
► View Available Hint(s)
Point A
Point B
Point C
Point D
Point E
Point F
Point G
Point H
Submit
Part B
In the figure showing the interference pattern for a double-slit setup, (Figure 1) which of the points shown represents
the fourth minimum?
► View Available Hint(s)

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Step 1: Here we have defined how the interference pattern is formed in young's double slit experiment

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