Multipoles, Electrostatics of Macroscopic Media, Dielectrics
|
|
- Joseph Parrish
- 6 years ago
- Views:
Transcription
1 Multipoles, Electrostatics of Macroscopic Media, Dielectrics 1 Reading: Jackson 4.1 through 4.4, 4.7 Consider a distribution of charge, confined to a region with r < R. Let's expand the resulting potential for r > R in spherical harmonics. Recall: (Jackson 3.70 and Topic 3, slide 34) (multipole expansion)
2 with (multipole moments) 2 Why is this useful? If we calculate using (1), then we have to do an integral over for each observation point With the multipole expansion, we only have to perform integrals to find the q lm. The number of q lm we calculate depends on the required accuracy (potentials from higher multipoles fall off as higher powers of r). Once we have the q lm, we can find for as many as we like without doing any more integrals. Since (Jackson 3.54 and Topic 3, slide 28)
3 Explicit evaluation in Cartesian coords: 3 where the electric dipole moment
4 The monopole (l = 0) contribution to is 4 The dipole (l = 1) contribution to is
5 Including the monopole, dipole, and quadrupole terms, 5 with Expansion beyond quadrupole gets messy. The electric field due to a dipole at the origin:
6 Note: NB: is a unit vector along, not a Cartesian unit vector. 1) Multipole moments depend on choice of origin. For example, for a point charge at the origin, only l = 0 multipole is non zero. If point charge is displaced from origin, higher order moments do not vanish. 6 2) The lowest non vanishing multipole moment is independent of the origin. Consider a charge dist localized to a volume V and subjected to a potential due to charges located outside of V. The potential energy of the charge dist in the external potential is If varies slowly over V, then Taylor expand it about an origin in V.
7 7 since the charge that produces is located outside V. Substituting this approx for into the integral yields
8 As a simple example, the interaction energy between 2 dipoles is 8 where points from 2 to 1, i.e., along SP 4.1, 4.2 Jackson section 4.3: When an electric field is applied to a dielectric, the dominant multipole moment of the response is the dipole. = dipole moment per unit volume Consider a volume where does not vary substantially; specifically a box with length d (along the direction of the dipole moments) and end face area A. d A total dipole moment in volume Ad : p = PAd = qd
9 9 If end face is slanted at angle, then area increases by 1/cos Diverging polarization yields bound charge pile up: Charge inside volume = = charge driven past bounding surface
10 To see these results directly from the dipole potential: 10 potential due to polarization (slide 4):
11 is the free charge volume density 11 with the electric displacement The equations of electrostatics in a dielectric are: For a linear, isotropic medium, e is the electric susceptibility is called the dielectric constant.
12 For a linear dielectric: 12 The final steps are for a uniform medium (i.e., doesn't vary with position). In this case, (The subscript f is often omitted.) => All problems in the medium are the same as in vacuum, except the field produced by a charge is reduced by factor 0 /. Boundary conditions at a surface with charge density (not including polarization charge): points from medium 1 to medium 2.
13 Example (Jackson sec 4.4): Find everywhere for z = 0 1 z q d (r,, z) 13 2 Boundary conditions: D and E are continuous => at z = 0,
14 For z > 0, use the method of images: charge q' at z' = d 14 For z < 0, try a charge q'' at z'' = d
15 Tangential component is E r 15 (This also follows from continuity of at z = 0.) From (1b) and (2b), We've found a potential that satisfies Poisson's eqn everywhere and the boundary conditions. Next, find the polarization charge on the plane z = 0:
16 16 Electrostatic energy in dielectric media Given charge density in a region of space, the work done to bring in a differential amount of new charge, with density is the potential due to the original charge.
17 17 0 if is localized For a linear medium,
18 If the dielectric is not linear, then it is not generally true that 18 In this case, the detailed history of the system must be taken into account, using eq. (1). SP
Notes: Most of the material presented in this chapter is taken from Jackson, Chap. 2, 3, and 4, and Di Bartolo, Chap. 2. 2π nx i a. ( ) = G n.
Chapter. Electrostatic II Notes: Most of the material presented in this chapter is taken from Jackson, Chap.,, and 4, and Di Bartolo, Chap... Mathematical Considerations.. The Fourier series and the Fourier
More informationChapter 5. Magnetostatics
Chapter 5. Magnetostatics 5.4 Magnetic Vector Potential 5.1.1 The Vector Potential In electrostatics, E Scalar potential (V) In magnetostatics, B E B V A Vector potential (A) (Note) The name is potential,
More informationDielectrics. Lecture 20: Electromagnetic Theory. Professor D. K. Ghosh, Physics Department, I.I.T., Bombay
What are dielectrics? Dielectrics Lecture 20: Electromagnetic Theory Professor D. K. Ghosh, Physics Department, I.I.T., Bombay So far we have been discussing electrostatics in either vacuum or in a conductor.
More informationJackson 6.4 Homework Problem Solution Dr. Christopher S. Baird University of Massachusetts Lowell
Jackson 6.4 Homework Problem Solution Dr. Christopher S. Baird University of Massachusetts Lowell PROBLEM: A uniformly magnetized and conducting sphere of radius R and total magnetic moment m = 4πMR 3
More informationMaxwell's Equations and Conservation Laws
Maxwell's Equations and Conservation Laws 1 Reading: Jackson 6.1 through 6.4, 6.7 Ampère's Law, since identically. Although for magnetostatics, generally Maxwell suggested: Use Gauss's Law to rewrite continuity
More informationCHAPTER 3 POTENTIALS 10/13/2016. Outlines. 1. Laplace s equation. 2. The Method of Images. 3. Separation of Variables. 4. Multipole Expansion
CHAPTER 3 POTENTIALS Lee Chow Department of Physics University of Central Florida Orlando, FL 32816 Outlines 1. Laplace s equation 2. The Method of Images 3. Separation of Variables 4. Multipole Expansion
More informationProblem Set #4: 4.1,4.7,4.9 (Due Monday, March 25th)
Chapter 4 Multipoles, Dielectrics Problem Set #4: 4.,4.7,4.9 (Due Monday, March 5th 4. Multipole expansion Consider a localized distribution of charges described by ρ(x contained entirely in a sphere of
More informationExpansion of 1/r potential in Legendre polynomials
Expansion of 1/r potential in Legendre polynomials In electrostatics and gravitation, we see scalar potentials of the form V = K d Take d = R r = R 2 2Rr cos θ + r 2 = R 1 2 r R cos θ + r R )2 Use h =
More information1 Fundamentals. 1.1 Overview. 1.2 Units: Physics 704 Spring 2018
Physics 704 Spring 2018 1 Fundamentals 1.1 Overview The objective of this course is: to determine and fields in various physical systems and the forces and/or torques resulting from them. The domain of
More informationSUMMARY PHYSICS 707 Electrostatics. E(x) = 4πρ(x) and E(x) = 0 (1)
SUMMARY PHYSICS 707 Electrostatics The basic differential equations of electrostatics are E(x) = 4πρ(x) and E(x) = 0 (1) where E(x) is the electric field and ρ(x) is the electric charge density. The field
More informationChapter 5. Magnetostatics
Chapter 5. Magnetostatics 5.1 The Lorentz Force Law 5.1.1 Magnetic Fields Consider the forces between charges in motion Attraction of parallel currents and Repulsion of antiparallel ones: How do you explain
More information4 Electric Fields in Matter
4 Electric Fields in Matter 4.1 Parity and Time Reversal: Lecture 10 (a) We discussed how fields transform under parity and time reversal. A useful table is Quantity Parity Time Reversal t Even Odd r Odd
More informationMultipole moments. November 9, 2015
Multipole moments November 9, 5 The far field expansion Suppose we have a localized charge distribution, confined to a region near the origin with r < R. Then for values of r > R, the electric field must
More informationTransformed E&M I homework. Multipole Expansion (Griffiths Chapter 3)
Transformed E&M I homework Multipole Expansion (Griffiths Chapter 3) Multipole Expansion Question 1. Multipole moment of charged wire CALCULATION; EXPANSION (U. Nauenberg, HW3, solutions available) A charge
More information1. (3) Write Gauss Law in differential form. Explain the physical meaning.
Electrodynamics I Midterm Exam - Part A - Closed Book KSU 204/0/23 Name Instructions: Use SI units. Where appropriate, define all variables or symbols you use, in words. Try to tell about the physics involved,
More informationClassical Field Theory: Electrostatics-Magnetostatics
Classical Field Theory: Electrostatics-Magnetostatics April 27, 2010 1 1 J.D.Jackson, Classical Electrodynamics, 2nd Edition, Section 1-5 Electrostatics The behavior of an electrostatic field can be described
More informationlim = F F = F x x + F y y + F z
Physics 361 Summary of Results from Lecture Physics 361 Derivatives of Scalar and Vector Fields The gradient of a scalar field f( r) is given by g = f. coordinates f g = ê x x + ê f y y + ê f z z Expressed
More informationDielectrics - III. Lecture 22: Electromagnetic Theory. Professor D. K. Ghosh, Physics Department, I.I.T., Bombay
Dielectrics - III Lecture 22: Electromagnetic Theory Professor D. K. Ghosh, Physics Department, I.I.T., Bombay We continue with our discussion of dielectric medium. Example : Dielectric Sphere in a uniform
More informationModule 2 : Electrostatics Lecture 9 : Electrostatic Potential
Module 2 : Electrostatics Lecture 9 : Electrostatic Potential Objectives In this lecture you will learn the following Electric Dipole and field due to a dipole Torque on a dipole in an inhomogeneous electric
More informationINTRODUCTION TO ELECTRODYNAMICS
INTRODUCTION TO ELECTRODYNAMICS Second Edition DAVID J. GRIFFITHS Department of Physics Reed College PRENTICE HALL, Englewood Cliffs, New Jersey 07632 CONTENTS Preface xi Advertisement 1 1 Vector Analysis
More informationNotes: Most of the material presented in this chapter is taken from Jackson, Chap. 5.
Chapter. Magnetostatics Notes: Most of the material presented in this chapter is taken from Jackson, Chap. 5..1 Introduction Just as the electric field vector E is the basic quantity in electrostatics,
More informationElectric fields in matter
Electric fields in matter November 2, 25 Suppose we apply a constant electric field to a block of material. Then the charges that make up the matter are no longer in equilibrium: the electrons tend to
More informationINSTRUCTORS MANUAL: TUTORIAL REVIEW 2 Separation of Variables, Multipole Expansion, Polarization
INSTRUCTORS MANUAL: TUTORIAL REVIEW 2 Separation of Variables, Multipole Expansion, Polarization Goals: To revisit the topics covered in the previous 4 weeks of tutorials and cement concepts prior to the
More informationl=0 The expansion coefficients can be determined, for example, by finding the potential on the z-axis and expanding that result in z.
Electrodynamics I Exam - Part A - Closed Book KSU 15/11/6 Name Electrodynamic Score = 14 / 14 points Instructions: Use SI units. Where appropriate, define all variables or symbols you use, in words. Try
More informationIndiana University Physics P331: Theory of Electromagnetism Review Problems #3
Indiana University Physics P331: Theory of Electromagnetism Review Problems #3 Note: The final exam (Friday 1/14 8:00-10:00 AM will be comprehensive, covering lecture and homework material pertaining to
More informationd 1 µ 2 Θ = 0. (4.1) consider first the case of m = 0 where there is no azimuthal dependence on the angle φ.
4 Legendre Functions In order to investigate the solutions of Legendre s differential equation d ( µ ) dθ ] ] + l(l + ) m dµ dµ µ Θ = 0. (4.) consider first the case of m = 0 where there is no azimuthal
More informationClassical Electrodynamics
Classical Electrodynamics Third Edition John David Jackson Professor Emeritus of Physics, University of California, Berkeley JOHN WILEY & SONS, INC. Contents Introduction and Survey 1 I.1 Maxwell Equations
More informationChapter 21 Electric Charge
Chapter 21 Electric Charge Historically people knew of electrostatic effects Hair attracted to amber rubbed on clothes People could generate sparks Recorded in ancient Greek history 600 BC Thales of Miletus
More informationElectric field lines are perpendicular to the equipotential lines
EQUIPOTENTIAL URFACE E = Electric field lines are perpendicular to the equipotential lines Electric field lines are opposite to the direction where maximum variation in the scalar potential occurs E =
More informationPhysics 169. Luis anchordoqui. Kitt Peak National Observatory. Thursday, February 22, 18
Physics 169 Kitt Peak National Observatory Luis anchordoqui 1 4.1 Capacitors A capacitor is a system of two conductors that carries equal and opposite charges A capacitor stores charge and energy in the
More informationGravity and action at a distance
Gravitational waves Gravity and action at a distance Newtonian gravity: instantaneous action at a distance Maxwell's theory of electromagnetism: E and B fields at distance D from charge/current distribution:
More informationMultipole Expansion for Radiation;Vector Spherical Harmonics
Multipole Expansion for Radiation;Vector Spherical Harmonics Michael Dine Department of Physics University of California, Santa Cruz February 2013 We seek a more systematic treatment of the multipole expansion
More informationElectrodynamics II: Lecture 9
Electrodynamics II: Lecture 9 Multipole radiation Amol Dighe Sep 14, 2011 Outline 1 Multipole expansion 2 Electric dipole radiation 3 Magnetic dipole and electric quadrupole radiation Outline 1 Multipole
More information3. Calculating Electrostatic Potential
3. Calculating Electrostatic Potential 3. Laplace s Equation 3. The Method of Images 3.3 Separation of Variables 3.4 Multipole Expansion 3.. Introduction The primary task of electrostatics is to study
More informationScattering. March 20, 2016
Scattering March 0, 06 The scattering of waves of any kind, by a compact object, has applications on all scales, from the scattering of light from the early universe by intervening galaxies, to the scattering
More informationChap. 1 Fundamental Concepts
NE 2 Chap. 1 Fundamental Concepts Important Laws in Electromagnetics Coulomb s Law (1785) Gauss s Law (1839) Ampere s Law (1827) Ohm s Law (1827) Kirchhoff s Law (1845) Biot-Savart Law (1820) Faradays
More informationPhysics 610: Electricity & Magnetism I
Physics 610: Electricity & Magnetism I [i.e. relativistic EM, electro/magneto-statics] [lin12.triumph.ca] [J-lab accelerator] [ixnovi.people.wm.edu] [Thywissen group, U. of Toronto] [nanotechetc.com] [wikipedia.org]
More informationCLASSICAL ELECTRODYNAMICS I Physics 6/75203 SPRING 2013
INSTRUCTOR: CLASSICAL ELECTRODYNAMICS I Physics 6/75203 SPRING 2013 Dr. Mark Manley manley@kent.edu 220 Smith Hall http://www.kent.edu/cas/physics/people/manley.cfm 330-672-2407 CLASS HOURS: 1:10-2:00
More informationSummary of time independent electrodynamics
hapter 10 Summary of time independent electrodynamics 10.1 Electrostatics Physical law oulomb s law charges as origin of electric field Superposition principle ector of the electric field E(x) in vacuum
More informationTUTORIAL 7. Discussion of Quiz 2 Solution of Electrostatics part 1
TUTORIAL 7 Discussion of Quiz 2 Solution of Electrostatics part 1 Quiz 2 - Question 1! Postulations of Electrostatics %&''()(*+&,-$'.)/ : % (1)!! E # $$$$$$$$$$ & # (2)!" E # #! Static Electric field is
More informationChapter 6. Magnetostatic Fields in Matter
Chapter 6. Magnetostatic Fields in Matter 6.1. Magnetization Any macroscopic object consists of many atoms or molecules, each having electric charges in motion. With each electron in an atom or molecule
More informationfiziks Institute for NET/JRF, GATE, IIT-JAM, JEST, TIFR and GRE in PHYSICAL SCIENCES
Content-ELECTRICITY AND MAGNETISM 1. Electrostatics (1-58) 1.1 Coulomb s Law and Superposition Principle 1.1.1 Electric field 1.2 Gauss s law 1.2.1 Field lines and Electric flux 1.2.2 Applications 1.3
More informationDiscipline Course-I. Semester-II. Paper No: Electricity and Magnetism. Lesson: Polarization and Dielectric Materials
Discipline CourseI SemesterII Paper No: Electricity and Magnetism Lesson: Polarization and Dielectric Materials Lesson Developer: Dr. Amit Choudhary College/ Department: Physics Department, Deshbandhu
More informationChapter 4. Electric Fields in Matter
Chapter 4. Electric Fields in Matter 4.1.2 Induced Dipoles What happens to a neutral atom when it is placed in an electric field E? The atom now has a tiny dipole moment p, in the same direction as E.
More informationELECTROMAGNETISM. Second Edition. I. S. Grant W. R. Phillips. John Wiley & Sons. Department of Physics University of Manchester
ELECTROMAGNETISM Second Edition I. S. Grant W. R. Phillips Department of Physics University of Manchester John Wiley & Sons CHICHESTER NEW YORK BRISBANE TORONTO SINGAPORE Flow diagram inside front cover
More information1 Fundamentals of laser energy absorption
1 Fundamentals of laser energy absorption 1.1 Classical electromagnetic-theory concepts 1.1.1 Electric and magnetic properties of materials Electric and magnetic fields can exert forces directly on atoms
More informationGalactic Astronomy 2016
10 Potential theory The study of dynamics is fundamental to any understanding of galaxies. The following few chapters provide a brief summary of the most important results. More details can be found in
More informationClass 11 : Magnetic materials
Class 11 : Magnetic materials Magnetic dipoles Magnetization of a medium, and how it modifies magnetic field Magnetic intensity How does an electromagnet work? Boundary conditions for B Recap (1) Electric
More informationA half submerged metal sphere (UIC comprehensive
Problem 1. exam) A half submerged metal sphere (UIC comprehensive A very light neutral hollow metal spherical shell of mass m and radius a is slightly submerged by a distance b a below the surface of a
More informationMUDRA PHYSICAL SCIENCES
MUDRA PHYSICAL SCIENCES VOLUME- PART B & C MODEL QUESTION BANK FOR THE TOPICS:. Electromagnetic Theory UNIT-I UNIT-II 7 4. Quantum Physics & Application UNIT-I 8 UNIT-II 97 (MCQs) Part B & C Vol- . Electromagnetic
More informationCHAPTER 11 RADIATION 4/13/2017. Outlines. 1. Electric Dipole radiation. 2. Magnetic Dipole Radiation. 3. Point Charge. 4. Synchrotron Radiation
CHAPTER 11 RADIATION Outlines 1. Electric Dipole radiation 2. Magnetic Dipole Radiation 3. Point Charge Lee Chow Department of Physics University of Central Florida Orlando, FL 32816 4. Synchrotron Radiation
More informationChapter 5 Summary 5.1 Introduction and Definitions
Chapter 5 Summary 5.1 Introduction and Definitions Definition of Magnetic Flux Density B To find the magnetic flux density B at x, place a small magnetic dipole µ at x and measure the torque on it: N =
More informationHomework Assignment 4 Solution Set
Homework Assignment 4 Solution Set PHYCS 442 7 February, 24 Problem (Griffiths 2.37 If the plates are sufficiently large the field near them does not depend on d. The field between the plates is zero (the
More informationCHAPTER 2. COULOMB S LAW AND ELECTRONIC FIELD INTENSITY. 2.3 Field Due to a Continuous Volume Charge Distribution
CONTENTS CHAPTER 1. VECTOR ANALYSIS 1. Scalars and Vectors 2. Vector Algebra 3. The Cartesian Coordinate System 4. Vector Cartesian Coordinate System 5. The Vector Field 6. The Dot Product 7. The Cross
More informationClassical Mechanics/Electricity and Magnetism. Preliminary Exam. August 20, :00-15:00 in P-121
Classical Mechanics/Electricity and Magnetism Preliminary Exam August 20, 2008 09:00-15:00 in P-121 Answer THREE (3) questions from each of the TWO (2) sections A and B for a total of SIX (6) solutions.
More informationContact Hours Face to Face: 1.5 hr lecture; 1.5 hr tutorial Online: hr (pace depends on student) lecture video and assessment
Academic Year 2018/19 Semester 2 Course Coordinator Dr. Koh Teck Seng Course Code PH2102 Course Title Electromagnetism Pre-requisites (MH1801 & MH2800 & PH1106) OR (MH1802 & MH1803 & MH2802 & PH1106) OR
More informationKINGS COLLEGE OF ENGINEERING DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING QUESTION BANK
KINGS COLLEGE OF ENGINEERING DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING QUESTION BANK SUB.NAME : ELECTROMAGNETIC FIELDS SUBJECT CODE : EC 2253 YEAR / SEMESTER : II / IV UNIT- I - STATIC ELECTRIC
More informationPrinciples of Mobile Communications
Communication Networks 1 Principles of Mobile Communications University Duisburg-Essen WS 2003/2004 Page 1 N e v e r s t o p t h i n k i n g. Wave Propagation Single- and Multipath Propagation Overview:
More informationCLASSICAL ELECTRICITY
CLASSICAL ELECTRICITY AND MAGNETISM by WOLFGANG K. H. PANOFSKY Stanford University and MELBA PHILLIPS Washington University SECOND EDITION ADDISON-WESLEY PUBLISHING COMPANY Reading, Massachusetts Menlo
More informationChapter 4. Electrostatics of Macroscopic Media
Chapter 4. Electrostatics of Macroscopic Meia 4.1 Multipole Expansion Approximate potentials at large istances 3 x' x' (x') x x' x x Fig 4.1 We consier the potential in the far-fiel region (see Fig. 4.1
More informationDielectric Polarization, Bound Charges, and the Electric Displacement Field
Dielectric Polarization, Bound Charges, and the Electric Displacement Field Any kind of matter is full of positive and negative electric charges. In a, these charges are bound they cannot move separately
More informationChapter Three: Propagation of light waves
Chapter Three Propagation of Light Waves CHAPTER OUTLINE 3.1 Maxwell s Equations 3.2 Physical Significance of Maxwell s Equations 3.3 Properties of Electromagnetic Waves 3.4 Constitutive Relations 3.5
More informationINTRODUCTION to the DESIGN and FABRICATION of IRON- DOMINATED ACCELERATOR MAGNETS
INTRODUCTION to the DESIGN and FABRICATION of IRON- DOMINATED ACCELERATOR MAGNETS Cherrill Spencer, Magnet Engineer SLAC National Accelerator Laboratory Menlo Park, California, USA Lecture # 1 of 2 Mexican
More informationJunior-level Electrostatics Content Review
Junior-level Electrostatics Content Review Please fill out the following exam to the best of your ability. This will not count towards your final grade in the course. Do your best to get to all the questions
More informationThe Raman Effect. A Unified Treatment of the Theory of Raman Scattering by Molecules. DerekA. Long
The Raman Effect A Unified Treatment of the Theory of Raman Scattering by Molecules DerekA. Long Emeritus Professor ofstructural Chemistry University of Bradford Bradford, UK JOHN WILEY & SONS, LTD Vll
More informationMagnetostatics and the vector potential
Magnetostatics and the vector potential December 8, 2015 1 The divergence of the magnetic field Starting with the general form of the Biot-Savart law, B (x 0 ) we take the divergence of both sides with
More informationUNIT-I Static Electric fields
UNIT-I Static Electric fields In this chapter we will discuss on the followings: Coulomb's Law Electric Field & Electric Flux Density Gauss's Law with Application Electrostatic Potential, Equipotential
More informationScattering cross-section (µm 2 )
Supplementary Figures Scattering cross-section (µm 2 ).16.14.12.1.8.6.4.2 Total scattering Electric dipole, a E (1,1) Magnetic dipole, a M (1,1) Magnetic quardupole, a M (2,1). 44 48 52 56 Wavelength (nm)
More informationFORMULA SHEET FOR QUIZ 2 Exam Date: November 8, 2017
MASSACHUSETTS INSTITUTE OF TECHNOLOGY Physics Department Physics 8.07: Electromagnetism II November 5, 207 Prof. Alan Guth FORMULA SHEET FOR QUIZ 2 Exam Date: November 8, 207 A few items below are marked
More informationA cylinder in a magnetic field (Jackson)
Problem 1. A cylinder in a magnetic field (Jackson) A very long hollow cylinder of inner radius a and outer radius b of permeability µ is placed in an initially uniform magnetic field B o at right angles
More information3 Constitutive Relations: Macroscopic Properties of Matter
EECS 53 Lecture 3 c Kamal Sarabandi Fall 21 All rights reserved 3 Constitutive Relations: Macroscopic Properties of Matter As shown previously, out of the four Maxwell s equations only the Faraday s and
More informationSupplementary Material for. Resonant Transparency and Non-Trivial Excitations in Toroidal Metamaterials
Supplementary Material for Resonant Transparency and Non-Trivial Excitations in Toroidal Metamaterials V. A. Fedotov 1, A. V. Rogacheva 1, V. Savinov 1, D. P. Tsai 2,3, N. I. Zheludev 1, 4 1 Optoelectronics
More informationElectrodynamics PHY712. Lecture 4 Electrostatic potentials and fields. Reference: Chap. 1 & 2 in J. D. Jackson s textbook.
Electrodynamics PHY712 Lecture 4 Electrostatic potentials and fields Reference: Chap. 1 & 2 in J. D. Jackson s textbook. 1. Complete proof of Green s Theorem 2. Proof of mean value theorem for electrostatic
More informationMULTIPOLE EXPANSIONS IN THE PLANE
MULTIPOLE EXPANSIONS IN THE PLANE TSOGTGEREL GANTUMUR Contents 1. Electrostatics and gravitation 1 2. The Laplace equation 2 3. Multipole expansions 5 1. Electrostatics and gravitation Newton s law of
More informationClassical Field Theory
April 13, 2010 Field Theory : Introduction A classical field theory is a physical theory that describes the study of how one or more physical fields interact with matter. The word classical is used in
More informationList of Comprehensive Exams Topics
List of Comprehensive Exams Topics Mechanics 1. Basic Mechanics Newton s laws and conservation laws, the virial theorem 2. The Lagrangian and Hamiltonian Formalism The Lagrange formalism and the principle
More information3.3 Capacitance, relative permittivity & dielectrics 4
3.3 Capacitance, relative permittivity & dielectrics 4 +Q d E Gaussian surface Voltage, V Q Fig. 3.2. Parallel plate capacitor with the plates separated by a distance d which have been charged by a power
More informationDifferential Operators and the Divergence Theorem
1 of 6 1/15/2007 6:31 PM Differential Operators and the Divergence Theorem One of the most important and useful mathematical constructs is the "del operator", usually denoted by the symbol Ñ (which is
More informationElectric and magnetic multipoles
Electric and magnetic multipoles Trond Saue Trond Saue (LCPQ, Toulouse) Electric and magnetic multipoles Virginia Tech 2017 1 / 22 Multipole expansions In multipolar gauge the expectation value of the
More informationPOLARIZATION AND MAGNETIZATION
POLARIZATION AND MAGNETIZATION Neutral matter is made of atoms and molecules. The polar molecules have built-in electric dipole moments p; normally, they are randomly oriented, but in presence of an external
More informationReview of Electrostatics. Define the gradient operation on a field F = F(x, y, z) by;
Review of Electrostatics 1 Gradient Define the gradient operation on a field F = F(x, y, z) by; F = ˆx F x + ŷ F y + ẑ F z This operation forms a vector as may be shown by its transformation properties
More informationChapter 4. Electrostatic Fields in Matter
Chapter 4. Electrostatic Fields in Matter 4.1. Polarization 4.2. The Field of a Polarized Object 4.3. The Electric Displacement 4.4. Linear Dielectrics 4.5. Energy in dielectric systems 4.6. Forces on
More informationChapter 1 Introduction
Plane-wave expansions have proven useful for solving numerous problems involving the radiation, reception, propagation, and scattering of electromagnetic and acoustic fields. Several textbooks and monographs
More informationLecture 11: Potential Energy Functions
Lecture 11: Potential Energy Functions Dr. Ronald M. Levy ronlevy@temple.edu Originally contributed by Lauren Wickstrom (2011) Microscopic/Macroscopic Connection The connection between microscopic interactions
More informationReview of Electrostatics
Review of Electrostatics 1 Gradient Define the gradient operation on a field F = F(x, y, z) by; F = ˆx F x + ŷ F y + ẑ F z This operation forms a vector as may be shown by its transformation properties
More informationNYU Physics Preliminary Examination in Electricity & Magnetism Fall 2011
This is a closed-book exam. No reference materials of any sort are permitted. Full credit will be given for complete solutions to the following five questions. 1. An impenetrable sphere of radius a carries
More informationModule I: Electromagnetic waves
Module I: Electromagnetic waves Lectures 10-11: Multipole radiation Amol Dighe TIFR, Mumbai Outline 1 Multipole expansion 2 Electric dipole radiation 3 Magnetic dipole and electric quadrupole radiation
More informationCitation for published version (APA): Kootstra, F. (2001). Time-dependent density functional theory for periodic systems s.n.
University of Groningen Time-dependent density functional theory for periodic systems Kootstra, Freddie IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish
More informationTheoretische Physik 2: Elektrodynamik (Prof. A-S. Smith) Home assignment 11
WiSe 22..23 Prof. Dr. A-S. Smith Dipl.-Phys. Matthias Saba am Lehrstuhl für Theoretische Physik I Department für Physik Friedrich-Alexander-Universität Erlangen-Nürnberg Problem. Theoretische Physik 2:
More informationAntennas and Propagation. Chapter 2: Basic Electromagnetic Analysis
Antennas and Propagation : Basic Electromagnetic Analysis Outline Vector Potentials, Wave Equation Far-field Radiation Duality/Reciprocity Transmission Lines Antennas and Propagation Slide 2 Antenna Theory
More informationTensor Taylor series method for vacuum effects
Tensor Taylor series method for vacuum effects M. W. Evans, H. Eckardt Civil List, A.I.A.S. and UPITEC (www.webarchive.org.uk, www.aias.us, www.atomicprecision.com, www.upitec.org) 3 Numerical and graphical
More informationLecture Notes for PHY 405 Classical Mechanics
Lecture Notes for PHY 405 Classical Mechanics From Thorton & Marion s Classical Mechanics Prepared by Dr. Joseph M. Hahn Saint Mary s University Department of Astronomy & Physics September 1, 2005 Chapter
More informationModern Optics Prof. Partha Roy Chaudhuri Department of Physics Indian Institute of Technology, Kharagpur
Modern Optics Prof. Partha Roy Chaudhuri Department of Physics Indian Institute of Technology, Kharagpur Lecture 09 Wave propagation in anisotropic media (Contd.) So, we have seen the various aspects of
More informationLecture notes for ELECTRODYNAMICS.
Lecture notes for 640-343 ELECTRODYNAMICS. 1 Summary of Electrostatics 1.1 Coulomb s Law Force between two point charges F 12 = 1 4πɛ 0 Q 1 Q 2ˆr 12 r 1 r 2 2 (1.1.1) 1.2 Electric Field For a charge distribution:
More informationMultipole Fields in the Vacuum Gauge. June 26, 2016
Multipole Fields in the Vacuum Gauge June 26, 2016 Whatever you call them rubber bands, or Poincaré stresses, or something else there have to be other forces in nature to make a consistent theory of this
More informationChapter 7. Time-Varying Fields and Maxwell s Equations
Chapter 7. Time-arying Fields and Maxwell s Equations Electrostatic & Time arying Fields Electrostatic fields E, D B, H =J D H 1 E B In the electrostatic model, electric field and magnetic fields are not
More informationarxiv: v2 [physics.acc-ph] 27 Oct 2014
Maxwell s equations for magnets A. Wolski University of Liverpool, Liverpool, UK and the Cockcroft Institute, Daresbury, UK arxiv:1103.0713v2 [physics.acc-ph] 27 Oct 2014 Abstract Magnetostatic fields
More informationLinear and nonlinear optical susceptibilities of Maxwell Garnett composites: Dipolar spectral theory
PHYSICAL REIEW B OLUME 60, NUMBER 24 15 DECEMBER 1999-II Linear and nonlinear optical susceptibilities of Maxwell Garnett composites: Dipolar spectral theory Mark I. Stockman* and Konstantin B. Kurlayev
More informationSelf-force: foundations and formalism
University of Southampton June 11, 2012 Motivation Extreme-mass-ratio inspirals solar-mass neutron star or black hole orbits supermassive black hole m emits gravitational radiation, loses energy, spirals
More information1. (3) Write Gauss Law in differential form. Explain the physical meaning.
Electrodynamics I Midterm Exam - Part A - Closed Book KSU 204/0/23 Name Electro Dynamic Instructions: Use SI units. Where appropriate, define all variables or symbols you use, in words. Try to tell about
More information