1. Light from a red laser passes through a single slit to form a diffraction pattern. If the width of the slit is increased by a factor of two, what happens to the width of the central maximum? Note: Assume that the angle 0 is sufficiently small so that (sin 0) is nearly equal to 0. a. The width of the central maximum increases by a factor of 4. b. The width of the central maximum decreases by a factor of 2. c. The width of the central maximum decreases by a factor of 4. d. The width of the central maximum increases by a factor of 2. e. The width of the central maximum does not change.

1. Light from a red laser passes through a single slit to form a diffraction pattern. If the width of the slit is increased by a factor of two, what happens to the width of the central maximum? Note: Assume that the angle 0 is sufficiently small so that (sin 0) is nearly equal to 0. a. The width of the central maximum increases by a factor of 4. b. The width of the central maximum decreases by a factor of 2. c. The width of the central maximum decreases by a factor of 4. d. The width of the central maximum increases by a factor of 2. e. The width of the central maximum does not change.

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter30: Atomic Physics

Section: Chapter Questions

Problem 53PE: (a) What is the distance between the slits of a diffraction grating that produces a first-order...

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