Refraction and Polarization of Light

Similar documents
Refraction and Polarization of Light

Reflection, Refraction and Polarization of Light Physics 246

Experiment 6. Snell s Law. Use Snell s Law to determine the index of refraction of Lucite.

Reflection, Refraction and Polarization of Light

Refraction of Light. c = m / s. n = c v. The index of refraction is never less than 1. Some common indices of refraction are listed below.

Polarization of Light

Outline The Refraction of Light Forming Images with a Plane Mirror 26-3 Spherical Mirror 26-4 Ray Tracing and the Mirror Equation

OPTICAL POTPOURRI (L-21)

Polarization of light

PHY385 Module 2 Student Guide. Concepts of this Module. Activity 1 The Law of Reflection. The Law of Reflection Snell s Law Total Internal Reflection

13. Brewster angle measurement

Index of Refraction and Total Internal Reflection

Reflection and Refraction of Light

ENGR142 PHYS 115 Geometrical Optics and Lenses

Geometrical Optics INTRODUCTION. Wave Fronts and Rays

Name Section Date. Experiment Reflection and Refraction

Purpose: To determine the index of refraction of glass, plastic and water.

Introduction. Experiment A: Snell s Law. Physics 1CL REFLECTION AND REFRACTION OF LIGHT Summer Session II 2010

IB-2 Polarization Practice

Exp No.(9) Polarization by reflection

Lab 9. Reflection and Refraction

Light and the Properties of Reflection & Refraction

Physics 6C. Wave Properties of Light. Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB

LECTURE 13 REFRACTION. Instructor: Kazumi Tolich

4.4 Polarisation [26 marks]

Refraction of Light Finding the Index of Refraction and the Critical Angle

Home Lab 7 Refraction, Ray Tracing, and Snell s Law

Laboratory 6: Light and the Laser

DETERMINATION OF BREWSTER S ANGLE FOR GLASS AND PLASTIC USING A POLARIZED MONOCHROMATIC LIGHT SOURCE. Utsav Hanspal. Physics Honors Research Paper

Chapter 26 Geometrical Optics

speed of light in vacuum = speed of light in the material

1.! Questions about reflected intensity. [Use the formulas on p. 8 of Light.] , no matter

Chapter 24. Wave Optics. Wave Optics. The wave nature of light is needed to explain various phenomena

Chapter 26 Geometrical Optics

Chapter 24. Wave Optics. Wave Optics. The wave nature of light is needed to explain various phenomena

Reflection & refraction

specular diffuse reflection.

NORTHERN ILLINOIS UNIVERSITY PHYSICS DEPARTMENT. Physics 211 E&M and Quantum Physics Spring Lab #7: Reflection & Refraction

Wavefronts and Rays. When light or other electromagnetic waves interact with systems much larger than the wavelength, it s a good approximation to

Physics 4C Chabot College Scott Hildreth

Refraction of Light. This bending of the ray is called refraction

Reflection and Refraction

Name: Lab Partner: Section:

dq dt I = Irradiance or Light Intensity is Flux Φ per area A (W/m 2 ) Φ =

Chapter 33 cont. The Nature of Light and Propagation of Light (lecture 2) Dr. Armen Kocharian

Part 1: Plane Mirrors!

Protocol for Lab. Fundamentals

Reflection and Refraction

Be careful not to leave your fingerprints on the optical surfaces of lenses or Polaroid sheets.

Lecture 24: TUE 20 APR 2010 Ch : E&M Waves

Lesson Plan Outline for Rainbow Science

Pre-Lab Quiz / PHYS 224 Dispersion and Prism

FINDING THE INDEX OF REFRACTION - WebAssign

Fresnel Reflection. angle of transmission. Snell s law relates these according to the

PY106 Class31. Index of refraction. Refraction. Index of refraction. Sample values of n. Rays and wavefronts. index of refraction: n v.

Internal Reflection. Total Internal Reflection. Internal Reflection in Prisms. Fiber Optics. Pool Checkpoint 3/20/2013. Physics 1161: Lecture 18

: Imaging Systems Laboratory II. Laboratory 2: Snell s Law, Dispersion and the Prism March 19 & 21, n 1 n 2

Optics: Reflection and Refraction (approx. completion time: 2.5 h) (3/28/11)

Reflection and Refraction

Chapter 24. Wave Optics

normal angle of incidence increases special angle no light is reflected

GEOMETRIC OPTICS. LENSES refract light, so we need to know how light bends when entering and exiting a lens and how that interaction forms an image.

Figure 1 - Refraction

GCE AS and A Level. Physics A. AS exams 2009 onwards A2 exams 2010 onwards. Unit 3X: Approved specimen question paper. Version 1.0

Diffraction. Single-slit diffraction. Diffraction by a circular aperture. Chapter 38. In the forward direction, the intensity is maximal.

Izmir Institute of Technology Department of Physics

Light: Geometric Optics

Chapter 38. Diffraction Patterns and Polarization

Lecture 17 (Polarization and Scattering) Physics Spring 2018 Douglas Fields

Dispersion Polarization

Chapter 24. Wave Optics

PHYSICS 116 POLARIZATION AND LIGHT MEASUREMENTS

Lab 10 - GEOMETRICAL OPTICS

37 (15 pts) Apply Snell s law twice (external, then internal) to find it emerges at the same angle.

Chapter 3. Physical phenomena: plane parallel plate. This chapter provides an explanation about how rays of light physically behave when

REFRACTION OF LIGHT INDEX NUMBER. Explain this observation (3 marks) 1 Pyramid Assignments / All subjects, All topics available

Lecture 14: Refraction

9. Polarization. 1) General observations [Room 310]

dq dt I = Irradiance or Light Intensity is Flux Φ per area A (W/m 2 ) Φ =

Light. Form of Electromagnetic Energy Only part of Electromagnetic Spectrum that we can really see

Light and refractive index

Today s Topic: Refraction / Snell s Law

Midterm II Physics 9B Summer 2002 Session I

Physics 1C, Summer 2011 (Session 1) Practice Midterm 2 (50+4 points) Solutions

Ch. 22 Properties of Light HW# 1, 5, 7, 9, 11, 15, 19, 22, 29, 37, 38

Physics 102: Lecture 17 Reflection and Refraction of Light

Geometrical Optics. Theory. N = normal to surface. n r > n i. n i. n r. PHY 192 Geometrical Optics Spring

ACTIVITY A FIRST LOOK AT REFRACTION OBJECTIVE To observe optical refraction and theorize the mechanism for the observation.

Radiometry (From Intro to Optics, Pedrotti 1-4) Radiometry is measurement of Emag radiation (light) Consider a small spherical source Assume a black

Physics 4C Chapter 33: Electromagnetic Waves

Dispersion (23.5) Neil Alberding (SFU Physics) Physics 121: Optics, Electricity & Magnetism Spring / 17

Lecture 24 EM waves Geometrical optics

LIGHT SCATTERING THEORY

Chapter 82 Example and Supplementary Problems

SESSION 5: INVESTIGATING LIGHT. Key Concepts. X-planation. Physical Sciences Grade In this session we:

Chapter 4. Experiment 2: Snell s Law of Refraction. 4.1 Introduction. Checkpoint

Chapter 18 Ray Optics

EXPERIMENT 8 PFUND REFRACTION

Experiment 8 Wave Optics

Image Formation by Refraction

Transcription:

Chapter 9 Refraction and Polarization of Light Name: Lab Partner: Section: 9.1 Purpose The purpose of this experiment is to demonstrate several consequences of the fact that materials have di erent indexes of refraction for light. Refraction, total internal reflection and the polarization of light reflecting from a nonmetallic surface will be investigated 9.2 Introduction Light can travel through many transparent media such as water, glass and air. When this happens the speed of light is no longer c =3 10 8 m/s (the speed in vacuum), but is less. This reduction in the speed depends on the material. This change in speed and direction is called refraction and is governed by Snell s Law of Refraction. n 1 sin 1 = n 2 sin 2 (9.1) The ratio of the speed of light in vacuum to that in the medium is called the index of refraction (n). The index of refraction is a number greater than or equal to one. The angles ( 1 and 2 )aremeasuredwithrespecttothenormal(perpendicular)totheinterfacebetween the two media (See Figure 9.1). When light passes from a medium of higher index of refraction to a medium with a lower index of refraction, the light ray can be refracted at 90 0. This phenomenon is called total internal reflection. For incident angles greater than c,thereisnorefractedbeam. The transmission of light by fiber-optic cable uses this e ect. The critical angle of incidence where total internal reflection occurs is given by: sin c = n 2 n 1 n 1 >n 2 (9.2) If this angle and the index of refraction of one of the two media is known, the index of refraction of the other medium can be found. 53

n 1 n 2 θ 1 θ reflected ray 1 refracted ray θ 2 Figure 9.1: Snell s Law for refraction showing the angles measured with respect to the normal Figure 9.2: Ray table setup for the Snell s Law measurement. When light strikes an interface between two media, the reflected light is partially (linearly) polarized. At one special angle, the light reflected from an interface between two media with indices of refraction n 1 and n 2 will be completely polarized. This is called the Brewster angle, B.TheBrewsterangleisgivenby: 9.3 Procedure tan B = n 2 n 1 (9.3) In the Snell s Law and total internal reflection portions of the experiment, the ray table and alaserareusedtomeasuretheindexofrefractionofthecylindricallens. Theraytable, laser, and cylindrical lens are shown in Figure 9.2. Special Cautions: Never look directly into the laser. Be careful when moving around the darkened room for the last part of the experiment. 54

9.3.1 Snell s Law Figure 9.3: Ray table setup for the Snell s law measurement Here we will consider the laser beam to be a parallel beam, meaning its diameter is always the same. We will use the laser beam to calculate the index of refraction of Lucite. The Lucite under consideration is a semi-circular disk (cylindrical lens). Place the ray table and base on the optics bench. Align the cylindrical lens on the ray table as shown in Figure 9.3 with the flat side facing the incident laser beam. The flat face of the cylindrical lens should be aligned and centered on the ray table line labeled Component. Align the laser so the beam passes horizontally through the cylindrical lens. The laser beam should be aligned with the line on the ray table labeled Normal. The laser should be placed on spacer blocks for the correct vertical alignment. To help see the incident and refracted beam, use a strip of transparent plastic. Rotate the ray table so the angle of incidence is 10 o.recordtheangleofincidenceand angle of refraction. Repeat the measurement for 10 o steps of the incident angle up to 80 o.recordthevaluesinthedatatable. Calculate the index of refraction of the cylindrical lens assuming the index of refraction of air is 1.0 for the eight data points in the data table and record the results in the table. Show one example calculation below. Calculate the mean value of the index of refraction of the cylindrical lens for the eight measurements. 55

1 2 index of refraction 10 0 20 0 30 0 40 0 50 0 60 0 70 0 80 0 Figure 9.4: Ray table setup for the total internal reflection measurement Mean value of index of refraction Compare your average value for the index of refraction to the standard value for Lucite (or Plexiglas) of 1.51, i.e., calculate the percentage error. Percentage error 9.3.2 Total Internal Reflection. Align the cylindrical lens on the ray table as shown in Figure 9.4 with the curved (round) side facing the incident laser beam. Adjust the beam so the beam passes through the cylindrical lens with an incident angle of 0 o.thebeamshouldpassstraight through the lens. With the incident laser beam remaining normal to the round part of the cylindrical lens, slowly rotate the table and observe the exiting beam. Continue rotating the table until the exiting beam is nearly parallel to the flat face of the lens. The beam may appear to suddenly jump from near parallel to the flat face to inside the lens. This angle is the critical angle, c.recordthecriticalangle. 56

Figure 9.5: Ray table setup for the Brewster s angle measurement Measured critical angle Assuming the index of refraction of air to be 1.0, calculate the index of refraction of the cylindrical lens. Show the calculation below and record the value. Calculated index of refraction Calculate the percentage di erence between the mean value of the index of refraction found in the Snell s Law experiment and the index of refraction found in the total internal reflection experiment. Percentage di erence for index values 9.3.3 Polarization and Brewster s Angle Before beginning this part of the measurement, observe the e ect on unpolarized ambient light with two polarizers. Look through the two polarizers. Rotate one polarizer with respect to the other polarizer. As you rotate you will notice the light intensity varies between almost complete transmission and complete extinction. The first polarizer allows the component of unpolarized light which is aligned along the polarization axis to pass through the polarizer. The transmitted light is then completely polarized. When the second polarizer s axis is aligned with the axis of the first polarizer, the light is almost completely transmitted. When the second polarizer s axis is perpendicular to the first polarizer s axis, the light is blocked. In this part of the experiment, we will generate polarized light by reflection at Brewster s angle and show the light is polarized using a single polarizer. The apparatus is shown in Figure 9.5 57

Figure 9.6: Arrangement for the Brewster s angle measurement Turn o the laser and secure it in a safe place on the lab table. Place the light source on the optics bench with the parallel ray lens on the front of the light source. Place the slit plate and single slit mask on a component holder. Arrange the ray table as shown in Figure 9.6. The flat side of the cylindrical lens should face the light source. Adjust the slit mask so a single ray of light passes through the center of the ray table along the normal line. The room should be darkened for this part of the experiment. Rotate the ray table until the angle between the reflected and refracted rays is 90 o. Place a polarizer on a component holder. Arrange this component holder so it is in line with the reflected ray. Look through the polarizer at the light source as seen reflected from the cylindrical lens. Rotate the polarizer slowly through all angles. The intensity of the reflected light should vary as the polarizer is rotated. Record the angle of reflection. Measured Brewster angle ( B ) What is the angle of polarization of the light i.e., where is the light most intense. Take 0 o to be when the polarizer is oriented vertically, before you rotate it. Assuming the index of refraction for air is 1.00, calculate the index of refraction for the cylindrical lens from the Brewster angle ( B ). 58

Index of Refraction from B Calculate the percentage di erence between the mean value of the index of refraction from the Snell s Law experiment to the value found from the Brewster angle. Percentage di erence Change the angle of reflection from the flat face of the cylindrical lens. Is the light completely polarized for other angles of reflection? Explain why. 9.3.4 Questions 1. Using Snell s Law, derive the critical angle for total internal reflection given in the text. 2. What is the speed of light in the plastic you measured? 3. It is critical that the flat face of the cylindrical lens face the laser for the Snell s Law experiment and the curved side face the laser for the total internal reflection measurement. Why? 59

9.4 Conclusion Write a detailed conclusion about what you have learned. Include all relevant numbers you have measured with errors. Sources of error should also be included. 60

2024 © technodocbox.com Privacy Policy | Terms of Service | Feedback