College Physics:
College Physics:
11th Edition
ISBN: 9781305965515
Author: SERWAY, Raymond A.
Publisher: Brooks/Cole Pub Co
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Chapter 24, Problem 42P

(a)

To determine

The number of directions on the other side of the array in which there is a maximum of intensity.

(a)

Expert Solution
Check Mark

Answer to Problem 42P

The number of directions on the other side of the array in which there is a maximum of intensity is three corresponding to the orders -1, 0 and +1.

Explanation of Solution

Given Info: The velocity of light is 343m/s , the frequency is 37.2kHz , the slit separation is 1.30cm and the maximum viewing angle is 90.0° .

Formula to calculate the order is,

|m|(dλ)sin|θ|

  • λ is the wavelength
  • m is the order
  • d is the grid separation
  • θ is the angle
  • v is the velocity of sound
  • f is the frequency

Use v/f for λ and rearrange the above equation.

|m|(dv/f)sin|θ|

Substitute 343m/s for v , 37.2kHz for f , 1.30cm for d and 90.0° for θ to find |m| .

|m|(((1.30cm)(1m102cm))343m/s/((37.2kHz)(103Hz1kHz)))sin|90.0°|1.41

Thus, the number of directions on the other side of the array in which there is a maximum of intensity is three corresponding to the orders -1, 0 and +1.

Conclusion:

The number of directions on the other side of the array in which there is a maximum of intensity is three corresponding to the orders -1, 0 and +1.

(b)

To determine

The angle for each of the directions relative to the direction of incident beam.

(b)

Expert Solution
Check Mark

Answer to Problem 42P

The angles for each of the directions relative to the direction of incident beam are 45.2°,0°and45.2° for orders -1, 0 and -1 respectively.

Explanation of Solution

Given Info: The velocity of light is 343m/s , the frequency is 37.2kHz , the slit separation is 1.30cm and the maximum viewing angle is 90.0° .

Formula to calculate the angle is,

θ=sin1(mλd)=sin1(m(v/f)d)

Substitute 343m/s for v , 37.2kHz for f , 1.30cm for d and 1 for m to find θ .

θ=sin1((1)(343m/s/((37.2kHz)(103Hz1kHz)))((1.30cm)(1m102cm)))=sin1(0.709)=45.2°

Substitute 343m/s for v , 37.2kHz for f , 1.30cm for d and 0 for m to find θ .

θ=sin1((0)(343m/s/((37.2kHz)(103Hz1kHz)))((1.30cm)(1m102cm)))=0°

Substitute 343m/s for v , 37.2kHz for f , 1.30cm for d and 1 for m to find θ .

θ=sin1((1)(343m/s/((37.2kHz)(103Hz1kHz)))((1.30cm)(1m102cm)))=sin1(0.709)=+45.2°

Thus, the angles for each of the directions relative to the direction of incident beam are 45.2°,0°and+45.2° for orders -1, 0 and -1 respectively.

Conclusion:

The angles for each of the directions relative to the direction of incident beam are 45.2°,0°and+45.2° for orders -1, 0 and -1 respectively.

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Chapter 24 Solutions

College Physics:

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Spectra Interference: Crash Course Physics #40; Author: CrashCourse;https://www.youtube.com/watch?v=-ob7foUzXaY;License: Standard YouTube License, CC-BY