Interference. Lecture 24. Chapter 17. The final stretch of the course. PHYS.1440 Lecture 24 A.Danylov Department of Physics and Applied Physics

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1 Lecture 24 Chapter 17 Interference The final stretch of the course Course website:

2 Today we are going to discuss: Chapter 17: Section

3 Interference A standing wave is the interference pattern produced when two waves of equal frequency travel in opposite directions. Standing Wave (Demo) In this section we will look at the interference of two waves traveling in the same direction.

In this section we will look at the interference of two waves traveling in the same direction.

4 Interference in One Dimension The pattern resulting from the superposition of two waves is often called interference. In this section we will look at the interference of two waves traveling in the same direction. This resultant wave travels The resulting amplitude is A 2a for maximum constructive interference. The resulting amplitude is A 0 for perfect destructive interference

5 Let s describe 1D interference mathematically Consider two traveling waves. They have: 1. The same direction, +x direction 2. The same amplitude, a 3. The same frequency, Let s find a displacement at point P at time t: P x,, 0 + Using a trig identity: 0 The phase of the wave The phase constant 0 tells us what the source is doing at t 0. cos Δ 2 sin 2 2 sin

The amplitude has a maximum value A = 2a if cos( /2) 1.

6 Constructive/destructive interference The amplitude: It is still a traveling wave where 1-2 is the phase difference between the two waves. The amplitude has a maximum value A = 2a if cos( /2) 1.,,,, Conditions for constructive interference: Similarly, the amplitude is zero, A=0 if cos( /2) 0. /,,,, Conditions for destructive interference

7 Let s look deeper in Δ 2-1 is the phase difference between the two waves. Conditions for constructive interference: destructive interference: So, there are two contributions to the phase difference: 1. pathlength difference inherent phase difference

8 Let s play with Inherent phase difference Question These are identical sources y 1 =ASin(kx- t+φ 10 ) What is the inherent phase difference? A) 0 B) /2 C) D) 2 y 2 =ASin(kx- t+φ 20 ) These are not identical sources: out of phase y 1 =ASin(kx- t+φ 10 ) y 1 =ASin(kx- t+φ 10 ) /2 / y 2 =ASin(kx- t+φ 20 ) y 2 =ASin(kx- t+φ 20 ) We have to shift Sin by to get Sin (to overlap them) We have to shift Cos by /2 to get Sin (to overlap them), so /

9 ConcepTest Two loudspeakers emit waves with. What, if anything, can be done to cause constructive interference between the two waves? 1D interference A) Move speaker 1 forward by 0.5 m B) Move speaker 1 forward by 1.0 m C) Move speaker 1 forward by 2.0 m D) Do nothing /

Let s separate the sources with a pathlength x

for destructive interference: For a constructive

separate them by an integer number of wavelength / For

10 What if sources are identical? Assume that the sources are identical 0. Let s separate the sources with a pathlength x Conditions for constructive interference: Conditions for destructive interference: For a constructive interference of two identical sources, we need to separate them by an integer number of wavelength / For a destructive interference of two identical sources, we need to separate them by an half integer number of wavelength

Noise-cancelling headphones Applications Sin(x) It

second sound specifically designed to cancel the

-Sin(x) Thin transparent films, placed on glass

11 Noise-cancelling headphones Applications Sin(x) It allows reducing unwanted sound by the addition of a second sound specifically designed to cancel the first (destructive interference). -Sin(x) Thin transparent films, placed on glass surfaces, such as lenses, can control reflections from the glass. Antireflection coatings on the lenses in cameras, microscopes, and other optical equipment are examples of thin-film coatings.

12 Interference in two and three dimensions

Interference conditions for Circular Waves, x r, where

A linear (1D) wave A circular (2D) or spherical (3D)

transform our interference conditions If the sources

13 Interference conditions for Circular Waves, x r, where r is the distance measured outward from the source. A linear (1D) wave A circular (2D) or spherical (3D) wave Similarly (x is replaced with r), we can transform our interference conditions If the sources are identical ( ), the interference is / Constructive if Destructive if

14 Example D interference between two loudspeakers Δ

15 Example Interference of two identical circular waves The figure shows two identical sources that are in phase. The path-length difference r determines whether the interference at a particular point is constructive or destructive.

16 ConcepTest Two in-phase sources emit sound waves of equal wavelength and intensity. At the position of the dot, 2D Interference A) The interference is constructive. B) The interference is destructive C) The interference is somewhere between constructive and destructive D) There s not enough information to tell about the interference...

17 Thank you

Interference. Lecture 21. Chapter 17. Physics II. Course website:

Interference. Lecture 21. Chapter 17. Physics II. Course website: Lecture 21 Chapter 17 Physics II Interference Course website: http://faculty.uml.edu/andriy_danylov/teaching/physicsii Today we are going to discuss: Chapter 17: Section 17.5-7 Interference A standing