Chapter 16 Interference and Diffraction. 16.1 - Interference Objectives: Describe how light waves interfere with each other to produce bright and dark.

Slides:



Advertisements
Similar presentations
Chapter 9 Light as a Wave.
Advertisements

Wave Nature of Light  Refraction  Interference  Young’s double slit experiment  Diffraction  Single slit diffraction  Diffraction grating.
The Wave Nature of Light Chapter 24. Properties of Light Properties of light include reflection, refraction, interference, diffraction, and dispersion.
The Wave Nature of Light
Diffraction The bending/spreading of waves as they go through gaps or around edges The effect is greatest when gap width is equal to or smaller than the.
Snell’s Law Snell’s Law describes refraction as light strikes the boundary between two media n1 sin q1 = n2 sin q2 The index of refraction of a pure vacuum.
last dance Chapter 26 – diffraction – part ii
Diffraction of Light Waves
Chapter 24 Wave Optics.
Chapter 24 Wave Optics.
UNIT 8 Light and Optics 1. Wednesday February 29 th 2 Light and Optics.
Chapter 34 The Wave Nature of Light; Interference
IVA. Electromagnetic Waves and Optics
Chapter 25: Interference and Diffraction
Chapter 24 Wave Optics.
Chapter 35 Interference (cont.).
I NTERFERENCE AND D IFFRACTION Chapter 15 Holt. Section 1 Interference: Combining Light Waves I nterference takes place only between waves with the same.
3: Interference, Diffraction and Polarization
Chapter 37 Wave Optics. Wave optics is a study concerned with phenomena that cannot be adequately explained by geometric (ray) optics.  Sometimes called.
An unpolarized beam of light is incident on a pane of glass (n = 1
Interference and the Wave Nature of Light
CHAPTER 37 : INTERFERENCE OF LIGHT WAVES
Chapter 16 Interference and Diffraction. Chapter 16 Objectives Define interference Compare constructive v destructive interference from slits Define diffraction.
Wave Nature of Light & Electromagnetic Waves History, Light is a Wave & Polarization History, Light is a Wave & Polarization.
Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu To View the presentation as a slideshow with effects select “View”
Diffraction is the bending of waves around obstacles or the edges of an opening. Huygen’s Principle - Every point on a wave front acts as a source of tiny.
Transverse or longitudinal waves transport energy from one point to another. Each particle in the medium vibrates or oscillates, and disturbs the neighbouring.
Chapter 16 Pretest Interference and Diffraction. 1. When monochromatic light is reflected from a thin transparent film, A) constructive interference occurs.
S-110 A.What does the term Interference mean when applied to waves? B.Describe what you think would happened when light interferes constructively. C.Describe.
I NTERFERENCE AND D IFFRACTION Chapter 15 Holt. Section 1 Interference: Combining Light Waves I nterference takes place between waves with the same wavelength.
Ch 16 Interference. Diffraction is the bending of waves around obstacles or the edges of an opening. Huygen’s Principle - Every point on a wave front.
Wave superposition If two waves are in the same place at the same time they superpose. This means that their amplitudes add together vectorially Positively.
Diffraction Introduction to Diffraction Patterns
Diffraction the ability of waves to bend around obstacles Newton tried to explain diffraction due to an attraction between light particles and edge of.
Light Wave Interference In chapter 14 we discussed interference between mechanical waves. We found that waves only interfere if they are moving in the.
Interference & Diffraction. Interference Like other forms of wave energy, light waves also combine with each other Interference only occurs between waves.
Diffraction & Interference of Light
Lecture Nine: Interference of Light Waves: I
The Wave Nature of Light
Lecture 24 Interference of Light.
Wave Optics.
Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Interference and Diffraction Chapter 15 Table of Contents Section.
Physics 1C Lecture 27A. Interference Treating light as a particle (geometrical optics) helped us to understand how images are formed by lenses and mirrors.
Even a single slit causes a diffraction pattern, because every point in the slit serves as a source of a wave. Different parts of the slit have different.
6.2 Two slit interference Coherence Two-Slit Interference Thin film Interference.
Chapter 15 Preview Objectives Combining Light Waves
Interference & Diffraction Light Part 4. Interference Like other forms of wave energy, light waves also combine with each other Interference only occurs.
Chapter15 Section 1 Interference. Objectives Describe how light waves interfere with each other to produce bright and dark fringes. Identify the conditions.
Interference and Diffraction
Chapter 24 Wave Optics. General Physics Review – optical elements.
Chapter 24 The Wave Nature of Light
Physical optics Done by P G LOGAN. Physical optics Physical optics deals with phenomena that depend on the wave nature of light. There are three types.
Chapter 24 Wave Optics. Young’s Double Slit Experiment Thomas Young first demonstrated interference in light waves from two sources in Light is.
Diffraction and Coherence 16-2 and CAN WAVES BEND AROUND CORNERS? ·Can you hear me when I stand around the corner and yell? ·What about light? Think.
The Space Movie.
Diffraction Topic 13.5 Outcomes You will describe, qualitatively, diffraction, interference and polarization You will describe, qualitatively, how.
Ch 16 Interference.
Interference of Light Waves
Wave superposition If two waves are in the same place at the same time they superpose. This means that their amplitudes add together vectorially Positively.
Young’s Double Slit Experiment.
The Wave Nature of Light
Interference and Diffraction of Waves
Interference and the Wave Nature of Light
How to Use This Presentation
Interference of Light Waves
Unit 2 Particles and Waves Interference
MSTC Physics C Chapter 24 Section 3.
Interference.
Interference and Diffraction
Presentation transcript:

Chapter 16 Interference and Diffraction

Interference Objectives: Describe how light waves interfere with each other to produce bright and dark fringes Identify the conditions required for interference to occur Predict the location of interference fringes using the equation for double-slit interference

Interference Occurs when waves combine by superposition Can be constructive (resultant wave has an amplitude greater than that of any of the individual component waves) Can be destructive (resultant wave has an amplitude less than that of either of the individual component waves)

Constructive Interference

Destructive Interference

Interference, cont. In phase: If the crest of one wave overlaps the crest of another wave, with a phase difference of 0 o Out of phase: If the crest of one wave overlaps the trough of another wave, with a phase difference of 180 o Coherence: when the phase difference between two waves is constant; the waves do not shift relative to each other over time

Interference Waves must have a constant phase difference (coherence) in order for interference to be observed. If interference is to be clearly observed, the interfering waves must also have the same wavelength (i.e., they must be the same color, also known as monochromatic) Coherence can be obtained using a single wave source. It cannot be obtained using two different sources.

Interference, cont. Double slit wave pattern, monochromatic light Double slit wave pattern, white light

Thin Film Interference Occurs due to differences in thickness of the film at various points

Thin Film Interference

Thin Film Interference notes:

Thin Film Interference

Thin Film Interference Problems: Determine the type of interference that occurs in the problem: where, what kind Remember that the wave reflected from the lower surface of the film has to travel 2x the thickness before returning to the upper surface, where it interferes with the portion of the wave that reflects at the upper surface

Demonstrating Interference Light passing through two narrow slits act as two light sources that are coherent. When the coherent waves constructively interfere, you see a bright stripe. When the the coherent waves destructively interfere, you see a dark stripe. The alternating dark and bright parallel bands are called fringes.

Demonstrating Interference, cont.

Predicting location of interference fringes d The bottom beam has to travel slightly farther than the top beam to meet at point P. This distance is called the path difference and is equal to d(sinθ), where d is the distance between the two slits. This path difference has to equal a whole number multiple of the wavelength to create constructive interference. The path difference would be a (multiple plus ½) of wavelength for destructive interference to occur.

Predicting location of interference fringes Constructive fringes (bright) : d(sinθ) = m m is the order number of the fringe. The center bright fringe is the zeroth order, or m=0 (when θ=0). This is also called the central maximum. The next bright fringe is the first order, m=1, etc.

Fringe calculation example The distance between two slits is 0.030mm. The second-order bright fringe is measured on a viewing screen at an angle of 2.15 o from the central maximum. What is the wavelength of the light? What do we know? d = 0.030mm = 3x10 -5 m θ = 2.15 o Second order means m=2 Bright fringe means constructive interference d(sinθ) = m = 5.63 x m

Diffraction Objectives: Describe how light waves diffract around obstacles and produce bright and dark fringes Calculate the position of fringes for a diffraction grating Describe how diffraction determines an optical instrument’s ability to resolve imagesnterference

Diffraction Is the spreading of light into a region behind an obstruction Occurs when waves pass through small openings, around obstacles, or by sharp edges

Interference - Coherence Coherence produces an interference pattern. In order to produce the interference pattern, the component waves producing coherence must be of the same wavelength.

Interference - Coherence Interference patterns are VERY predictable. These patterns are called diffraction patterns if the light comes from a single slit (various portions of a single wave interfere), but interference patterns if the waves added come from two or more openings.

Interference (Diffraction) caused by Thin Slits Patterns of light and dark parallel bands (fringes) appear on viewing screen The light fringes are due to constructive interference (light fringes are called maxima) The dark fringes are due to destructive interference (dark fringes are called minima)

Interference/Diffraction is caused by Three Common Types of Slits Single Slit Double Slit Diffraction Grating

Single slit diffraction pattern Produces one very large, bright central maximum band that is twice as wide as the secondary maximas. The dark bands are called minima.

Compare to double-slit pattern….

Interference – Double Slit (Young’s)

Young’s Double Slit

Young’s Double Slit Equations also, y/L = λ/d θ < 5 o Bright fringes d(sin θ) = mλ Dark fringes d(sin θ) = (m + ½ )λ

Diffraction Gratings Use diffraction and interference to disperse light. If white light is used, the light will break into its component colors (like a prism)

Diffraction Gratings The result is separation and repeated color blocks, from m=0 (zero order) to infinity. In reality, only a few m values are seen.

Diffraction Gratings

Diffraction Equations for diffraction gratings d(sin θ) = mλ m = 0, + 1, + 2,... for bright fringes y/L = λ/d will NOT work because θ > 5 o So, use tan θ = y/L to find θ Then use d(sin θ) = mλ

Diffraction grating example problem Monochromatic light from a helium-neon laser ( =632.8nm) Shines at a right angle to the surface of a diffraction grating that contains 150,500 lines/m. Find the angles at which one would observe the first and second order maxima.

Compact Discs are Diffraction Gratings The disc has alternating rows of pits (inscribed data) and smooth surfaces. The data pits don’t reflect nearly as much light as the smooth surfaces in between them, And the reflected light constructively interferes. Depending on the direction of the incoming light, the orientation of the disc and the light’s wavelength, you’ll see a “rainbow” of colors coming off the disc.

Diffraction in the World