B.TECH FIRST YEAR ACADEMIC YEAR: 2020-2021 COURSE NAME: ENGINEERING PHYSICS COURSE CODE : PY1001 LECTURE SERIES NO : 01 (ONE) CREDITS : 4 MODE OF DELIVERY : ONLINE (POWER POINT PRESENTATION) FACULTY : DR. NILANJAN HALDER EMAIL-ID : nilanjan.halder@jaipur.manipal.edu SESSION OUTCOME “UNDERSTAND THE BASIC PRINCIPLES OF WAVE OPTICS” ASSIGNMENT QUIZ MID TERM EXAMINATION –I END TERM EXAMINATION ASSESSMENT CRITERIA’S INTERFERENCE Topics Two source interference Double-slit interference Coherence Intensity in double slit interference Interference from thin film Michelson’s Interferometer Text Book: PHYSICS VOL 2 by Halliday, Resnick and Krane (5th Edition) TWO-SOURCE INTERFERENCE When identical waves from two sources overlap at a point in space, the combined wave intensity at that point can be greater or less than the intensity of either of the two waves. This effect is called interference. The interference is constructive when the net intensity is greater than the individual intensities. The interference is destructive when the net intensity is less than individual intensities. TWO-SOURCE INTERFERENCE Maximal constructive interference of two waves occurs when their phase difference is 0, 2, 4 , … (the waves are inphase) Complete destructive interference of two waves occur when their phase difference is , 3 , 5 , … (the waves are 180o out of phase) TWO-SOURCE INTERFERENCE INTERFERENCE PATTERN PRODUCED BY WATER WAVES IN A RIPPLE TANK Maxima: where the shadows show the crests and valleys Minima: where the shadows are less clearly visible DOUBLE-SLIT INTERFERENCE A train of plane light waves is incident on two narrow parallel slits separated by distance d (<<). The interference pattern on the screen consists of bright and dark fringes. DOUBLE-SLIT INTERFERENCE Consider two coherent sources S1 and S2 separated by a distance ‘d’ and kept at a distance ‘D’ from the screen. For D>>d, we can approximate rays r1 and r2 as being parallel. Path difference between two waves from S1 & S2 (separated by a distance ‘d’) on reaching a point P on a screen at a distance ‘D’ from the sources is S1b = d sin . DOUBLE-SLIT INTERFERENCE For maximum at point P S1b = m m = 0, 1, 2, . . . Which can be written as, d sin = m m = 0, 1, 2, . . . m = 0 is the central maximum. For minimum at point P S1b (m 21 ) m = 0, 1, 2, . . . Which can be written as, d sin (m 21 ) m = 0, 1, 2, . . . DOUBLE-SLIT INTERFERENCE • For small value of , we can make following approximation. sin sin tan y D • Path difference: d sin S1b y d D DOUBLE-SLIT INTERFERENCE mth maximum is located at ym given by m d or ym ym D D m d where m = 0, 1, 2, . . . DOUBLE-SLIT INTERFERENCE Separation between adjacent maxima (for small ) is independent of m y y m1 y m D D (m 1) m d d D y d The spacing between the adjacent minima is same the spacing between adjacent maxima. DOUBLE-SLIT INTERFERENCE YOUNG’S DOUBLE SLIT EXPERIMENT • Double slit experiment was first performed by Thomas Young in 1801. • So double slit experiment is known as Young’s Experiment. • He used sun light as source for the experiment. • In his experiment, he allowed sun light to pass through narrow opening (S0) and then through two openings (S1 and S2). DOUBLE-SLIT INTERFERENCE Problem: SP 41-1 The double slit arrangement is illuminated by light of wavelength 546nm. The slits are 12mm apart and the screen on which interference pattern appears is 55cm away. a) What is the angular position of (i) first minima and (ii) tenth maxima? b) What is the separation between two adjacent maxima? DOUBLE-SLIT INTERFERENCE Problem: E 41-2 Monochromatic light illuminates two parallel slits a distance d apart The first maximum is observed at an angular position of 15°. By what percentage should d be increased or decreased so that the second maximum will instead be observed at 15° ? DOUBLE-SLIT INTERFERENCE Problem: E 41-5 A double-slit arrangement produces interference fringes for sodium light (wavelength = 589 nm) that are 0.23° apart. For what wavelength would the angular separation be 10% greater ? Assume that the angle is small. DOUBLE-SLIT INTERFERENCE Problem: E 41-8 In an interference experiment in a large ripple tank (see Fig 41-2) the coherent vibrating sources are placed 120 mm apart. The distance between maxima 2.0 m away is 180 mm. If the speed of the ripples is 25 cm/s, calculate the frequency of the vibrating sources. DOUBLE-SLIT INTERFERENCE Problem: E 41-11 Sketch the interference pattern expected from using two pin-holes rather than narrow slits. COHERENCE For interference pattern to occur, the phase difference at point on the screen must not change with time. A SECTION OF INFINITE WAVE A WAVE TRAIN OF FINITE LENGTH L This is possible only when the two sources are completely coherent. If the two sources are completely independent light sources, no fringes appear on the screen (uniform illumination) . This is because the two sources are completely incoherent. COHERENCE A SECTION OF INFINITE WAVE A WAVE TRAIN OF FINITE LENGTH L Common sources of visible light emit light wave trains of finite length rather than an infinite wave. The degree of coherence decreases as the length of wave train decreases. COHERENCE A SECTION OF INFINITE WAVE Two waves are said to be coherent when they are of : • same amplitude A WAVE TRAIN OF FINITE LENGTH L • same frequency • same phase or are of a constant phase difference Laser light is highly coherent whereas a laboratory monochromatic light source (sodium vapor lamp) may be partially coherent. INTENSITY IN DOUBLE SLIT INTERFERENCE Electric field components at P due to S1 and S2 are, E1= E0 sin ωt & E2= E0 sin (ωt + ) respectively. Resultant field E = E1 + E2 INTENSITY IN DOUBLE SLIT INTERFERENCE Resultant of E1= E0 sin ωt & E2= E0 sin (ωt + ) Phasor Rotating vector. ADDITION OF TWO VECTORS USING PHASORS E2 Let two vectors be, E1= E0 sin ωt & E0 E0 E1 E2= E0 sin (ωt + ) Resultant field E = E1 + E2 ωt + ωt INTENSITY IN DOUBLE SLIT INTERFERENCE Resultant of E1= E0 sin ωt & E2= E0 sin (ωt + ) From phasor diagram, E = E1 + E 2 E0 = E sin(t + ) E2 E = 2E0 cos sin(t + ) But = /2. So above eqn can be written as, E = 2 E0 cos(/2) sin(wt+/2) E E0 E1 ωt INTENSITY IN DOUBLE SLIT INTERFERENCE E = 2 E0 cos(/2) sin(wt+/2) So intensity at an arbitrary point P on the screen due to interference of two sources having phase difference ; I 4 E cos 2 2 0 2 4 0 cos 2 where E2 is intensity due to single source 0 0 2 INTENSITY IN DOUBLE SLIT INTERFERENCE PHASE AND PATH DIFFERENCE Phase difference Path difference 2 Path difference corresponds to phase difference of 2. INTENSITY IN DOUBLE SLIT INTERFERENCE 4 0 cos 2 2 where E 2 is intensity due to single source 0 0 Since 2dsin/ , 2 d 4 0 cos sin From above equation, At maxima : 2 m or At minima : ( 2 m 1) where m 0, 1, 2, . . . d sin or m d sin (m 1 ) 2 INTENSITY IN DOUBLE SLIT INTERFERENCE INTENSITY IN DOUBLE SLIT INTERFERENCE Problem: SP 41-2 Find graphically the resultant E(t) of the following wave disturbances. E1 = E0 sin t E2 = E0 sin (t + 15o) E3 = E0 sin (t + 30o) E4 = E0 sin (t + 45o) INTENSITY IN DOUBLE SLIT INTERFERENCE Problem: E 41-15 Source A of long-range radio waves leads source B by 90 degrees. The distance rA to a detector is greater than the distance rB by 100m. What is the phase difference at the detector? Both sources have a wavelength of 400m. INTENSITY IN DOUBLE SLIT INTERFERENCE Problem: E 41-18 Find the sum of the following quantities (a) graphically, using phasors; and (b) using trigonometry: y1 = 10 sin (t) y2 = 8.0 sin (t + 30°) INTERFERENCE FROM THIN FILMS A film of thickness of the order of a micron. Thickness of the film is comparable with the wavelength. Greater thickness spoils the coherence of the light to produce colour. A soapy water film on a vertical loop viewed by reflected light INTERFERENCE FROM THIN FILMS The region ac looks bright or dark for an observer depending on the path difference between the rays r1 and r2. INTERFERENCE FROM THIN FILMS Phase change on Reflection It has been observed that if the medium beyond the interface has a higher index of refraction, the reflected wave undergoes a phase change of (=180o). If the medium beyond the interface has a lower index of refraction, there is no phase change of the reflected wave. Phase changes on reflection at a junction between two strings of different linear mass densities. INTERFERENCE FROM THIN FILMS OPTICAL PATH • Distance traveled by light in a medium in the time interval of ‘t’ is d = vt • Refractive index n = c/v • Hence, ct = nd • nd Optical path. • Optical path is the distance traveled by light in vacuum in same time ‘t’. • If n is wavelength in the film of refractive index n and is the wavelength in vacuum then n = / n INTERFERENCE FROM THIN FILMS Equations for Thin Film Interference: Normal incidence (i = 0) Path difference = 2 d + (½) n BACK SURFACE Constructive interference: 2 d + (½) n = m n m = 1, 2, 3, . . . (maxima) Destructive interference: 2 d + (½) n = (m+½) n m = 0, 1, 2, . . . (minima) INTERFERENCE FROM THIN FILMS WEDGE SHAPED FILM In wedge – shaped thin film, constructive interference occurs in certain part of the film [2 d + (½) n = m n] and destructive interference in others [2 d + (½) n = (m+½) n]. Then bands of maximum and minimum intensity appear, called fringes of constant thickness. INTERFERENCE FROM THIN FILMS Problem: SP 41-3 A soap film (n=1.33) in air is 320nm thick. If it is illuminated with white light at normal incidence, what color will it appear to be in reflected light? INTERFERENCE FROM THIN FILMS Problem: SP 41-4 Lenses are often coated with thin films of transparent substances such as MgF2 (n=1.38) to reduce the reflection from the glass surface. How thick a coating is required to produce a minimum reflection at the center of the visible spectrum? ( wavelength = 550nm) INTERFERENCE FROM THIN FILMS Problem: E 41-23 A disabled tanker leaks kerosene (n=1.20) into the Persian Gulf, creating a large slick on top of water (n = 1.33). (a)If you look straight down from aeroplane on to the region of slick where thickness is 460nm, for which wavelengths of visible light is the reflection is greatest? (b)If you are scuba diving directly under this region of slick, for which wavelengths of visible light is the transmitted intensity is strongest? INTERFERENCE FROM THIN FILMS Problem: E 41-25 If the wavelength of the incident light is λ = 572 nm, rays A and B in Fig 41-24 are out of phase by 1.50 λ. Find the thickness d of the film. INTERFERENCE FROM THIN FILMS Problem: E 41-29 A broad source of light (wavelength = 680nm) illuminates normally two glass plates 120 mm long that touch at one end and are separated by a wire 0.048mm in diameter at the other end. How many bright fringes appear over 120 mm distance? INTERFERENCE FROM THIN FILMS Newton’s rings (sample problem 41-5): Constructive interference 2d = (m - ½) (n = 1 for air film) d r R 1 R R2 r 2 2 r R R 1 R 1 2 using binomial expansion 2 1 r d R R 1 . . . 2 R r2 2R INTERFERENCE FROM THIN FILMS Newton’s rings Substituting d in 2d = (m - ½) we get r m 21 R m 1, 2, . . . (maxima) INTERFERENCE FROM THIN FILMS Problem: E41-33 In a Newton’s ring experiment, the radius of curvature R of the lens is 5.0m and its diameter is 20mm. (a) How many ring are produced? (b) How many rings would be seen if the arrangement is immersed in water (n = 1.33)? (Assume wavelength = 589nm) MICHELSON’S INTERFEROMETER Light from an extended monochromatic source P falls on a half-silvered mirror M. The incident beam is divided into reflected and transmitted beams of equal intensity. These two beams travel almost in perpendicular directions and will be reflected normally from movable mirror (M2) and fixed mirror (M1). MICHELSON’S INTERFEROMETER The two beams finally proceed towards a telescope (T) through which interference pattern of circular fringes will be seen. The interference occurs because the two light beams travel different paths between M and M1 or M2. Each beam travels its respective path twice. When the beams recombine, their path difference is 2 (d2 – d1) MICHELSON’S INTERFEROMETER The path difference can be changed by moving mirror M2. As M2 is moved, the circular fringes appear to grow or shrink depending on the direction of motion of M2. New rings appear at the center of the interference pattern and grow outward or larger rings collapse disappear at the center as they shrink. MICHELSON’S INTERFEROMETER For the center of the fringe pattern to change from bright dark and to bright again, the path difference between two beams must change by one wavelength, which means that mirror M2 moves through a distance of /2. If N fringes cross the field of view when mirror M2 is moved by d, then d = N (/2) d is measured by a micrometer attached to M2. Thus microscopic length measurements can be made by this interferometer. MICHELSON’S INTERFEROMETER Problem: SP 41-6 Yellow light (wavelength = 589nm) illuminates a Michelson interferometer. How many bright fringes will be counted as the mirror is moved through 1.0 cm? MICHELSON’S INTERFEROMETER An airtight chamber 5.0 cm long with glass windows is placed in one arm of a Michelson’s interferometer as indicated in Fig 41-28 . Light of wavelength λ = 500 nm is used. The air is slowly evacuated from the chamber using a vacuum pump. While the air is being removed, 60 fringes are observed to pass through the view. From these data find the index of refraction of air at atmospheric pressure. Problem: E41-40 QUESTIONS – INTERFERENCE What is the necessary condition on the path length difference (and phase difference) between two waves that interfere (A) constructively and (B) destructively ? Obtain an expression for the fringe-width in the case of interference of light of wavelength λ, from a double-slit of slitseparation d. Explain the term coherence. Obtain an expression for the intensity of light in double-slit interference using phasor-diagram. QUESTIONS – INTERFERENCE Draw a schematic plot of the intensity of light in a double-slit interference against phase-difference (and path-difference). Explain the term reflection phase-shift. Obtain the equations for thin-film interference. Explain the interference-pattern in the case of wedge-shaped thin-films. Obtain an expression for the radius of mth order bright ring in the case of Newton’s rings. Explain Michelson’s interferometer. Explain how microscopic length measurements are made in this.