DOCSLIB.ORG

Chapter 8 Polarization

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Chapter 8 Polarization Phys 322 Chapter 8 Lecture 22 Polarization Polarization by scattering Scattering can polarize light Scattering can depolarize light Polarization by reflection Reminder: Fresnel equations show r||=0 at B - Brewster angle 1 B tan n2 n1 At Brewster angle reflected and transmitted rays form right angle B Reflected light will be fully polarized at B Fresnel equations 2 2 tan i t R r R|| 2 Fresnel equations tan i t 2 sin sin i t i t R r 2 sin i t sini t tan r i t || tan … i t Reflectance of unpolaized light: R R R || 2 Fresnel equations Multiple plate polarizer Degree of polarization: V I p Itot analyzing polarizer I I V max min Imax Imin detector Glare is horizontally polarized Puddle reflection viewed Puddle reflection viewed through polarizer that through polarizer that transmits only horizontally transmits only vertically polarized light polarized light Light reflected into our eyes from the puddle reflects at about Brewster's Angle. So parallel (i.e., vertical) polarization sees zero reflection. Polarizer sunglasses transmit only vertically polarized light. Polarizers are very useful in photography. Without a polarizer With a polarizer The effect of a polarizer is probably the one “filter” effect that you can’t reproduce later using Photoshop! Reminder: Dichroism = selective absorption of light of certain polarization Linear dichroism - selective absorption of one of the two P-state (linear) orthogonal polarizations Circular dichroism - selective absorption of L-state or R-state circular polarizations Using dichroic materials one can build a polarizer Dichroic crystals Anisotropic crystal structure: one polarization is absorbed more than the other Example: tourmaline Elastic constants for electrons may be different along two axes Polaroid 1928: dichroic sheet polarizer, J-sheet long tiny crystals of herapathite aligned in the plastic sheet Edwin Land 1938: H-sheet 1909-1991 Attach Iodine molecules to polymer molecules - molecular size iodine wires Presently produced: HN-38, HN-32, HN-22 Birefringence Elastic constants for electrons may be different along axes Resonance frequencies will be different for light polarized Refraction index depends on along different axes polarization: birefringence Dichroic crystal - absorbs one of the orthogonal P-states, transmits the other Optic axis of a crystal: the direction of linear polarization along which the resonance is different from the other two axes (assuming them equal) Calcite (CaCO3) Ca C O Image doubles Ordinary rays (o-rays) - unbent Extraordinary rays (e-rays) - bend Calcite (CaCO3) emerging rays are orthogonaly polarized Principal plane - any plane that contains optical axis Principal section - principal plane that is normal to one of the cleavage surfaces Birefringence and Huygens’ principle Crystal structure and birefringence NaCl - cubic crystal Four 3-fold symmetry axes - optically isotropic Anisotropic, uniaxial birefringent crystals: hexagonal, tetragonal, trigonal Uniaxial crystal: atoms are arranged symmetrically around optic axis O-wave - E everywhere is perpendicular to the optic axis, no c/v When E is parallel to optic axis: ne c/v|| Birefringence ne - no principal indices of refraction Calcite: (ne - no) = -0.172 (negative uniaxial crystal) Crystal structure and birefringence Negative uniaxial crystal (calcite) Positive uniaxial crystal (quartz, ice) Biaxial crystals Two optic axes and three principal indices of refraction Orthorhombic, monoclinic, triclinic Example: mica, KH2Al3(SiO4)3 Birefringent polarizers Nicol prism Glan-Thompson Wollaston prism polarizer 1828, William Nicol Retarders The two orthogonal P-states develop mutual phase shift as they pass through a retarder After propagating through: E E|| E polarized light phase shift: E E|| E birefringence extraordinary 2 in-phase ordinary dne no 0 in vacuum direction of polarization: E|| E0|| coskx t fast axis - the one that propagates faster slow axis - the one that propagates slower E E0 coskx t Full-wave plate 2 dn n e o = m.2, m=…,-1,0,+1,… 0 E|| E0|| coskx t Alternatively: dne no m0 E E0 coskx t full wave - no observable effect Note: n=n(), and it is generally true only for one wavelength Half-wave plate = +m.2, m=…,-1,0,+1,… 2 dne no 0 dne no 0 / 2 m0 E|| E0|| coskx t E E0 coskx t Polarization is rotated around the optic axis Special case: =45o Polarization is rotated by 90o Quarter-wave plate . 2 = /2 +m 2, m=…,-1,0,+1,… dne no 0 dne no 0 / 4 m0 E|| E0|| coskx t E E coskx t Linear polarization is converted into 0 circular/elliptical and vice versa Reflective retarders Total internal reflection: phase shift between the two components. Glass - n=1.51, and 45o shift occurs at incidence angle 54.6o. Fresnel rhomb Unlike devices that use birefringent materials this is achromatic Circular polarizer Can you make a polarizer that transmits right circularly polarized light but not the left circularly polarized light?.
Load more

Recommended publications
  • Polarization of Light: Malus' Law, the Fresnel Equations, and Optical Activity
    Polarization of light: Malus' law, the Fresnel equations, and optical activity. PHYS 3330: Experiments in Optics Department of Physics and Astronomy, University of Georgia, Athens, Georgia 30602 (Dated: Revised August 2012) In this lab you will (1) test Malus' law for the transmission of light through crossed polarizers; (2) test the Fresnel equations describing the reflection of polarized light from optical interfaces, and (3) using polarimetry to determine the unknown concentration of a sucrose and water solution. I. POLARIZATION III. PROCEDURE You will need to complete some background reading 1. Position the fixed \V" polarizer after mirror \M" before your first meeting for this lab. Please carefully to establish a vertical polarization axis for the laser study the following sections of the \Newport Projects in light. Optics" document (found in the \Reference Materials" 2. Carefully adjust the position of the photodiode so section of the course website): 0.5 \Polarization" Also the laser beam falls entirely within the central dark read chapter 6 of your text \Physics of Light and Optics," square. by Peatross and Ware. Your pre-lab quiz cover concepts presented in these materials AND in the body of this 3. Plug the photodiode into the bench top voltmeter write-up. Don't worry about memorizing equations { the and observe the voltage { it should be below 200 quiz should be elementary IF you read these materials mV; if not, you may need to attenuate the light by carefully. Please note that \taking a quick look at" these [anticipating the validity off Malus' law!] inserting materials 5 minutes before lab begins will likely NOT be the polarizer on a rotatable arm \R" upstream of adequate to do well on the quiz.
    [Show full text]
  • Fresnel Rhombs As Achromatic Phase Shifters for Infrared Nulling Interferometry: First Experimental Results
    Fresnel Rhombs as Achromatic Phase Shifters for Infrared Nulling Interferometry: First experimental results Hanot c.a, Mawet D.a, Loicq J.b, Vandormael D.b, Plesseria J.Y.b, Surdej J.a, Habraken s.a,b alnstitut d'Astrophysique et de Geophysique, University of Liege, 17 allee du 6 Aout, B-4000, Sart Tilman, Belgium; bCentre Spatial de Liege, Avenue du Pre-Aily, B-4031, Liege-Angleur, Belgium ABSTRACT One of the most critical units of nulling interferometers is the Achromatic Phase Shifter. The concept we propose here is based on optimized Fresnel rhombs, using the total internal reflection phenomenon, modulated or not. The total internal reflection induces a phase shift between the polarization components of the incident light. We present the principles, the current status of the prototype manufacturing and testing operations, as well as preliminary experiments on a ZnSe Fresnel rhomb in the visible that have led to a first error source assessment study. Thanks to these first experimental results using a simple polarimeter arrangement, we have identified the bulk scattering as being the main error source. Fortunately, we have experimentally verified that the scattering can be mitigated using spatial filters and does not decrease the phase shifting capabilities of the ZnSe Fresnel rhomb. Keywords: Fresnel Rhomb, Achromatic Phase Shifters, nulling interferometry, subwavelength gratings, Zinc Selenide, bulk scattering 1. INTRODUCTION The detection of extrasolar planets and later on the presence of life on them is one of the most interesting and ambitious astrophysical projects for the next decades. Up to now, despite our technological progresses, most exoplanets have been detected using indirect methods.
    [Show full text]
  • Lecture 26 – Propagation of Light Spring 2013 Semester Matthew Jones Midterm Exam
    Physics 42200 Waves & Oscillations Lecture 26 – Propagation of Light Spring 2013 Semester Matthew Jones Midterm Exam Almost all grades have been uploaded to http://chip.physics.purdue.edu/public/422/spring2013/ These grades have not been adjusted Exam questions and solutions are available on the Physics 42200 web page . Outline for the rest of the course • Polarization • Geometric Optics • Interference • Diffraction • Review Polarization by Partial Reflection • Continuity conditions for Maxwell’s Equations at the boundary between two materials • Different conditions for the components of or parallel or perpendicular to the surface. Polarization by Partial Reflection • Continuity of electric and magnetic fields were different depending on their orientation: – Perpendicular to surface = = – Parallel to surface = = perpendicular to − cos + cos − cos = cos + cos cos = • Solve for /: − = !" + !" • Solve for /: !" = !" + !" perpendicular to cos − cos cos = cos + cos cos = • Solve for /: − = !" + !" • Solve for /: !" = !" + !" Fresnel’s Equations • In most dielectric media, = and therefore # sin = = = = # sin • After some trigonometry… sin − tan − = − = sin + tan + ) , /, /01 2 ) 45/ 2 /01 2 * = - . + * = + * )+ /01 2+32* )+ /01 2+32* 45/ 2+62* For perpendicular and parallel to plane of incidence. Application of Fresnel’s Equations • Unpolarized light in air ( # = 1) is incident
    [Show full text]
  • The Fresnel Equations and Brewster's Law
    The Fresnel Equations and Brewster's Law Equipment Optical bench pivot, two 1 meter optical benches, green laser at 543.5 nm, 2 10cm diameter polarizers, rectangular polarizer, LX-02 photo-detector in optical mount, thick acrylic block, thick glass block, Phillips multimeter, laser mount, sunglasses. Purpose To investigate polarization by reflection. To understand and verify the Fresnel equations. To explore Brewster’s Law and find Brewster’s angle experimentally. To use Brewster’s law to find Brewster’s angle. To gain experience working with optical equipment. Theory Light is an electromagnetic wave, of which fundamental characteristics can be described in terms of the electric field intensity. For light traveling along the z-axis, this can be written as r r i(kz−ωt) E = E0e (1) r where E0 is a constant complex vector, and k and ω are the wave number and frequency respectively, with k = 2π / λ , (2) λ being the wavelength. The purpose of this lab is to explore the properties the electric field in (1) at the interface between two media with indices of refraction ni and nt . In general, there will be an incident, reflected and transmitted wave (figure 1), which in certain cases reduce to incident and reflected or incident and transmitted only. Recall that the angles of the transmitted and reflected beams are described by the law of reflection and Snell’s law. This however tells us nothing about the amplitudes of the reflected and transmitted Figure 1 electric fields. These latter properties are defined by the Fresnel equations, which we review below.
    [Show full text]
  • A Sensitive Spectropolarimeter for the Measurement
    A SENSITIVE SPECTROPOLARIMETER FOR THE MEASUREMENT OF CIRCULAR POLARIZATION OF LUMINESCENCE A Thesis Presented to The Faculty of the College of Engineering and Technology Ohio University In Partial Fulfillment of the Requirements for the Degree Master of Science By Ziad I. AI-Akir, June, 1990 DlHtft7~~·"E:RsaTY LI~~RY ACKNOWLEDGEMENT With gratitude and constancy, I praise the Almighty Allah for the grace and favors that He bestowed on me. Without His guidance and blessing, I would not be able to achieve any good deed in this life. I wish to extend my genuine appreciation to my advisor Dr. Henryk Lozykowski, for his teachings, assistance, encouragement and helpful suggestions. A special appreciation goes to Mr. V. K. Shastri and Mr. T. Lee for their assistance and valuable help during the preparation of this thesis. Finally, I would like to thank my brothers: Mohammed EI-Gamal, Amer AI-shawa, Abdulbaset AI-Abadleh and Rabah Odeh for their encouragement and all the brothers who helped me without knowing it. DEDICATION This thesis is dedicated to my family in Palestine and Kuwait, who have been a great source of blessing, motivation and encouragement. CONTENTS CHAPTER ONE Introduction 1 1.1 Circular Polarization of Luminescence 2 1.2 SPC in Luminescence Measurements 3 1.3 Objectives........... 5 CHAPTER TWO Literature Review......... 8 2.1 The Nature ofLight 8 2.2 Light in Matter 12 2.3 Semiconductor Materials 13 2.3.1 Intrinsic and Extrinsic Semiconductors. 15 2.3.2 Direct and Indirect Semiconductors ............... 16 2.4 Photoluminescence in Semiconductors...................... 18 2.5 Polarization 22 2.5.1 Linear Polarization 22 2.5.2 Circular Polarization 24 2.5.3 Elliptical Polarization..................................
    [Show full text]
  • Polarized Light 1
    EE485 Introduction to Photonics Polarized Light 1. Matrix treatment of polarization 2. Reflection and refraction at dielectric interfaces (Fresnel equations) 3. Polarization phenomena and devices Reading: Pedrotti3, Chapter 14, Sec. 15.1-15.2, 15.4-15.6, 17.5, 23.1-23.5 Polarization of Light Polarization: Time trajectory of the end point of the electric field direction. Assume the light ray travels in +z-direction. At a particular instance, Ex ˆˆEExy y ikz() t x EEexx 0 ikz() ty EEeyy 0 iixxikz() t Ex[]ˆˆEe00xy y Ee e ikz() t E0e Lih Y. Lin 2 One Application: Creating 3-D Images Code left- and right-eye paths with orthogonal polarizations. K. Iizuka, “Welcome to the wonderful world of 3D,” OSA Optics and Photonics News, p. 41-47, Oct. 2006. Lih Y. Lin 3 Matrix Representation ― Jones Vectors Eeix E0x 0x E0 E iy 0 y Ee0 y Linearly polarized light y y 0 1 x E0 x E0 1 0 Ẽ and Ẽ must be in phase. y 0x 0y x cos E0 sin (Note: Jones vectors are normalized.) Lih Y. Lin 4 Jones Vector ― Circular Polarization Left circular polarization y x EEe it EA cos t At z = 0, compare xx0 with x it() EAsin tA ( cos( t / 2)) EEeyy 0 y 1 1 yxxy /2, 0, E00 EA Jones vector = 2 i y Right circular polarization 1 1 x Jones vector = 2 i Lih Y. Lin 5 Jones Vector ― Elliptical Polarization Special cases: Counter-clockwise rotation 1 A Jones vector = AB22 iB Clockwise rotation 1 A Jones vector = AB22 iB General case: Eeix A 0x A B22C E0 i y bei B iC Ee0 y Jones vector = 1 A A ABC222 B iC 2cosEE00xy tan 2 22 EE00xy Lih Y.
    [Show full text]
  • Exam: Optics and Optical Design
    Dept of Physics LTH Exam: Optics and Optical design Instructions: The five problems are not ordered by increasing difficulty. For each problem a maximum of six points will be given. Fifteen points are required for passing the exam. Observe that solutions without reasonable motivation are not acceptable, even if the final answer is correct. You are allowed to bring: For the first problem: no help For the other: Calculator, TEFYMA, the course book. 1. a) Explain the differences between homogeneous, isotropic, and dispersive media. b) Large beam splitters in the shape of windows are used in supermarkets to supervise the customers or by the police in interrogation rooms. Explain why the clerk in the shop behind the window can see you, but you cannot see him/her. (Tip: It has nothing to with polarization. In principle, any window can do, if the lighting is chosen correctly.) a) b) Figure 1. a) Imaging with a thick lens. b) Equivalent ray diagram. 2. A thick convex-plane lens with a radius R and refractive index n is surrounded by air according to figure 1a. a) Determine the ray-transfer matrix of the system between the first surface and the focal plane. b) Give a formula for the distance d2 as a function of R n and d. The thick lens can be replaced with a plane (principal plane) where all the refractions occur (figure 1b). Then the focal point F is located at the distance f from this plane. c) Show that the distance f of the lens is given by the formula: R f n 1 d) Show that this is the focal length of the lens when it can be assumed to be a thin lens.
    [Show full text]
  • Optical Modeling of Nanostructures
    Optical modeling of nanostructures Phd Part A Report Emil Haldrup Eriksen 20103129 Supervisor: Peter Balling, Søren Peder Madsen January 2017 Department of Physics and Astronomy Aarhus University Contents 1 Introduction 3 2 Maxwell’s Equations 5 2.1 Macroscopic form ................................. 5 2.2 The wave equation ................................ 6 2.3 Assumptions .................................... 7 2.4 Boundary conditions ............................... 7 2.5 Polarization conventions ............................. 7 3 Transfer Matrix Method(s) 9 3.1 Fresnel equations ................................. 9 3.2 The transfer matrix method ........................... 9 3.3 Incoherence .................................... 11 3.4 Implementation .................................. 14 4 The Finite Element Method 15 4.1 Basic principle(s) ................................. 15 4.2 Scattered field formulation ............................ 17 4.3 Boundary conditions ............................... 17 4.4 Probes ....................................... 19 4.5 Implementation .................................. 19 5 Results 20 5.1 Nanowrinkles ................................... 20 5.2 The two particle model .............................. 24 6 Conclusion 28 6.1 Outlook ....................................... 28 Bibliography 29 Front page illustration: Calculated field enhancement near a gold nanostar fabricated by EBL. The model geometry was constructed in 2D from a top view SEM image using edge detection and extruded to 3D. 1 Introduction Solar
    [Show full text]
  • Approaches for Achieving Broadband Achromatic Phase Shifts for Visible Nulling Coronagraphy
    Approaches for Achieving Broadband Achromatic Phase Shifts for Visible Nulling Coronagraphy Matthew R. Bolcar' and Richard G. Lyon NASA Goddard Space Flight Center, 8800 Greenbelt Rd., Greenbelt, MD 20771 ABSTRACT Visible nulling coronagraphy is one of the few approaches to the direct detection and characterization of Jovian and Terrestrial exoplanets that works with segmented aperture telescopes. Jovian and Terrestrial planets require at least 10-9 and 10-10 image plane contrasts, respectively, within the spectral bandpass and thus require a nearly achromatic "'-phase difference between the arms of the interferometer. An achromatic "'-phase shift can be achieved by several techniques, including sequential angled thick glass plates of varying dispersive materials, distributed thin-film multilayer coatings, and techniques that leverage the polarization-dependent phase shift of total-internal reflections. Herein we describe two such techniques: sequential thick glass plates and Fresnel rhomb prisms. A viable technique must achieve the achromatic phase shift while simultaneously minimizing the intensity difference, chromatic beam spread and polarization variation between each arm. In this paper we describe the above techniques and report on efforts to design, model, fabricate, align the trades associated with each technique that will lead to an implementations of the most promising one in Goddard's Visible Nulling Coronagraph (VNC). Keywords: coronagraphy, interferometry, achromatic phase shift 1. INTRODUCTION The direct observation of Terrestrial planets in the visible bandwidth would allow for spectroscopic analysis to determine planetary composition, as well as the presence of water and the possibility to support life. To achieve direct detection, an instrument must be capable of high-<:ontrast imaging, or differentiating the 10 orders-of-magnitude difference between the host star's diffracted light and that reflected by an orbiting Terrestrial planet.
    [Show full text]
  • EXPERIMENT 3 Fresnel Reflection
    EXPERIMENT 3 Fresnel Reflection 1. Reflectivity of polarized light The reflection of a polarized beam of light from a dielectric material such as air/glass was described by Augustin Jean Fresnel in 1823. While his derivation was based on an elastic theory of light waves, the same results are found with electromagnetic theory. The ratio of the reflected intensity to the incident intensity is called the reflectivity of the surface. It depends on the polarization of the incident light wave. Let be the angle of incidence and be the angle of transmission. Snell’s law relates these according to the refractive index in each media and : ( ) ( ) (1) The reflectivity for light polarized parallel to the plane of incidence (known as p-polarized light) is ( ) (2) ( ) but for light polarized perpendicular to the plane of incidence (known as s-polarized light) it is ( ) (3) ( ) Notice that for p-polarized light the denominator of the right hand side will be infinite when the sum ( ) . The angle of 1 incidence when this happens is called Brewster’s angle, . For light polarized in the plane of incidence, no energy is reflected at Brewster’s angle, i.e. 2. Making the measurements Getting started: A He-Ne laser (632.8 nm) beam is reflected from the front face of a prism on a rotating table. You can read the angle of rotation of the table from the precision index and vernier. It is very important to locate the center of the prism over the axis of rotation. Do this as best you can by eye.
    [Show full text]
  • Chapter 8 Polarization
    Phys 322 Chapter 8 Lecture 22 Polarization Reminder: Exam 2, October 22nd (see webpage) Dichroism = selective absorption of light of certain polarization Linear dichroism - selective absorption of one of the two P-state (linear) orthogonal polarizations Circular dichroism - selective absorption of L-state or R-state circular polarizations Using dichroic materials one can build a polarizer Dichroic crystals Anisotropic crystal structure: one polarization is absorbed more than the other Example: tourmaline Elastic constants for electrons may be different along two axes Polaroid 1928: dichroic sheet polarizer, J-sheet long tiny crystals of herapathite aligned in the plastic sheet Edwin Land 1938: H-sheet 1909-1991 Attach Iodine molecules to polymer molecules - molecular size iodine wires Presently produced: HN-38, HN-32, HN-22 Birefringence Elastic constants for electrons may be different along axes Resonance frequencies will be different for light polarized Refraction index depends on along different axes polarization: birefringence Dichroic crystal - absorbs one of the orthogonal P-states, transmits the other Optic axis of a crystal: the direction of linear polarization along which the resonance is different from the other two axes (assuming them equal) Calcite (CaCO3) Ca C O Image doubles Ordinary rays (o-rays) - unbent Extraordinary rays (e-rays) - bend Calcite (CaCO3) emerging rays are orthogonaly polarized Principal plane - any plane that contains optical axis Principal section - principal plane that is normal to one of the cleavage
    [Show full text]
  • FRESNEL RHOMBS Mounted Unmounted Mounting Suggestion
    OPTICAL COMPONENTS FRESNEL RHOMBS COATINGS ● Rotate polarization, operates over a wide wavelength range ● λ/2 rhomb is two optically contacted λ/4 rhombs Due to unequal phase shifts arising in orthogonally polarized λ/4 Fresnel rhomb λ/2 Fresnel rhomb components of an incident wave at total internal reflection, Fresnel W Rhombs are used to alter the polarization type of radiation. They 1 I nd are designed so that two full internal reflections inside a rhomb OWS provide π/2 phase difference between the ortho go nally polarized 120 components of radiation. Hence, if there is a 45° angle between 140 & F the polarization of the linearly polarized incident plane, the emerg- I l TE ing beam is circularly polarized, i. e. the rhomb effect is similar D r S to that of a quarter-waveplate. Therefore, two identical Fresnel rhombs, installed in series, will provide π/2 phase difference similar to that of a half-waveplate, i. e. the device can rotate the beam polarization plane by 90°, leaving the beam direction invariable. M6 L M λ/2 rhomb with mount IRRORS Due to the low dispersion of the refractive index of the materials being used Fresnel rhombs are achromatic SPECIFICATIONS over a wide spectral range. Material BK7, UV FS Operating spectral range BK7: 400–2000 nm UV FS: 210–400 nm Air-Spaced Fresnel Rhombs are Surface quality 20-10 scratch & dig (MIL-PRF-13830B) available on request for high power Surface flatness λ/10 @ 633 nm (all polished surfaces) Retardation tolerance ±2° L applications. ENSES Broad band AR coating R < 1% Laser damage threshold > 0.5 J/cm2, 10 nsec pulse, 1064 typical Unmounted Catalogue Wavelength Clear Price, Material Retardation Mounting Suggestion number range, nm aperture, mm EUR 481-0210 600–900 λ/2 10 368 481-0410 600–900 λ/4 10 186 PRISMS Mounted BK7 481-0212 400–700 λ/2 10 368 Fresnel Rhomb 481-0414 400–700 λ/4 10 186 481-1210 210–400 λ/2 10 491 UV FS 481-1410 210–400 λ/4 10 296 Fresnel rhombs with other dimensions and parameters or coatings as well as unmounted rhombs are available upon request.
    [Show full text]