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COURSE INFORMATION
Course CodeCourse TitleL+P HourSemesterECTS
FIZ 501ADVANCED ELECTROMAGNETIC THEORY - I3 + 02nd Semester7,5

COURSE DESCRIPTION
Course Level Master's Degree
Course Type Elective
Course Objective The aim of this course is to present the interaction of non-relativistic charged particles with electromagnetic fields.
Course Content Introduction Electrostatics, Boundary-value Problems in Electrostatics, Multipoles and Dielectrics in Electrostatics, Magnetostatics, Maxwell Equations and Conservation Laws, Electromagnetic Waves, Radiating Systems
Prerequisites No the prerequisite of lesson.
Corequisite No the corequisite of lesson.
Mode of Delivery Face to Face

COURSE LEARNING OUTCOMES
1To learn the electrostatic concept.
2 To learn the solutions to laplace equations
3Learning of the electric field concepts.
4Learning of the magnetic field in the matter and outside of the matter.
5 To learn the maxwell equations and applications of the maxwell equations.
6Learning the electromagnetic waves and radiation.

COURSE'S CONTRIBUTION TO PROGRAM
PO 01PO 02PO 03PO 04PO 05PO 06PO 07PO 08PO 09
LO 00144       
LO 00232 44  4 
LO 00332       
LO 00432  4  4 
LO 00532 4   4 
LO 00632  4  4 
Sub Total1914 812  16 
Contribution320120030

ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
ActivitiesQuantityDuration (Hour)Total Work Load (Hour)
Course Duration (14 weeks/theoric+practical)14342
Hours for off-the-classroom study (Pre-study, practice)14684
Mid-terms13030
Final examination13939
Total Work Load

ECTS Credit of the Course






195

7,5
COURSE DETAILS
 Select Year   


 Course TermNoInstructors
Details 2019-2020 Fall1SEVGİ ÖZDEMİR KART


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Course Details
Course Code Course Title L+P Hour Course Code Language Of Instruction Course Semester
FIZ 501 ADVANCED ELECTROMAGNETIC THEORY - I 3 + 0 1 Turkish 2019-2020 Fall
Course Coordinator  E-Mail  Phone Number  Course Location Attendance
Prof. Dr. SEVGİ ÖZDEMİR KART ozsev@pau.edu.tr FEN B0203 %70
Goals The aim of this course is to present the interaction of non-relativistic charged particles with electromagnetic fields.
Content Introduction Electrostatics, Boundary-value Problems in Electrostatics, Multipoles and Dielectrics in Electrostatics, Magnetostatics, Maxwell Equations and Conservation Laws, Electromagnetic Waves, Radiating Systems
Topics
WeeksTopics
1 Introduction to Electrostatic, Coulomb’s Law, The Electric Field, Continuous Charge Distributions, Field Lines and Gauss’s Law, The Divergence of E Vector, Applications of Gauss’s Law
2 The Curl of E Vector, Introduction to Potential, Comments on Potential, Poisson’s Equation and Laplace’s Equation, The Potential of a Localized Charge Distribution, Electrostatic Boundary Conditions
3 The Work Done to Move a Charge, The Energy of a Point Charge Distribution, The Energy of a Continuous Charge Distribution, Comments on Electrostatic Energy, Basic Properties of Conductors, Induced Charges, Surface Charge and the Force on a Conductor, Capacitors
4 Basic Properties of Laplace’s Equation, Boundary Conditions and Uniqueness Theorems, The Classic Image Problem, Induced Surface Charge, Force and Energy, Other Image Problems
5 Separation of Variables in Cartesian Coordinates, Separation of Variables in Spherical Polar Coordinates
6 Multipole Expansions at Large Distances, The Monopole and Dipole Terms, Origin of Coordinates in Multipole Expansions, The Electric Field of an Ideal Dipole, Dielectrics, Induced Dipoles, Alignment of Polar Molecules, Polarization
7 Interpretation of Physical Charges, The Field Inside a Dielectric, Gauss’s Law in the Presence of Dielectric, A Deceptive Parallel, Boundary Conditions
8 Susceptibility, Permittivity and Dielectric Constant, Boundary Value Problems with Linear Dielectrics, Energy in Dielectric Systems, Forces on Dielectrics, Introduction to Magnetostatic, Magnetic Fields, Magnetic Forces, Currents
9 Midterm
10 Steady Currents, The Magnetic Field of a Steady Current and The Biot-Savart Law, Straight-Line Currents, The Divergence and Curl of B Vector, The Applications of Ampere’s Law, Comparison of Magnetostatics and Electrostatics The Vector Potential, Magnetostatic Boundary Conditions, Multipole Expansion of the Vector Potential, Summary and Problem Solutions
11 Magnetic Materials, Torques and Forces on Magnetic Dipoles, Effect of a Magnetic Field on Atomic Orbits, Magnetization, Bound Currents, Physical Interpretation of Bound Currents, The Magnetic Field Inside Matter, Ampere’s Law in Magnetized Materials, A Deceptive Parallel, Magnetic Susceptibility and Permeability, Ferromagnetism
12 Ohm’s Law, Electromotive Force, Motional emf, Electromagnetic Induction, Inductance, Energy in Magnetic Fields, Electrodynamics Before Maxwell, How Maxwell Fixed Up Ampere’s Law, Maxwell’s Equations and Magnetic Charge, Maxwell Equations Inside Matter, Boundary Conditions, Scalar and Vector Potentials, Gauge Transformations, Coulomb Gauge and Lorentz Gauge
13 Electromagnetic waves
14 Radiation systems
Materials
Materials are not specified.
Resources
ResourcesResources Language
Elektromanyetik Teori, David J. Griffiths, Çeviren: Prof. Dr. Bekir Karaoğlu Elektromanyetik Teori, David J. Griffiths, Çeviren: Prof. Dr. Basri ÜnalTürkçe
Foundations of Electromagnetic Theory, J. Reitz, F. Milford, R. W. Christy (1992) English
Classical Electromagnetic Theory, J. Vanderlinde (1993) English
Course Assessment
Assesment MethodsPercentage (%)Assesment Methods Title
Final Exam50Final Exam
Midterm Exam50Midterm Exam
L+P: Lecture and Practice
PQ: Program Learning Outcomes
LO: Course Learning Outcomes