Nov 22, 2024  
2016-2017 Undergraduate Academic Catalog 
    
2016-2017 Undergraduate Academic Catalog [ARCHIVED CATALOG]

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PH 2020 - Physics II-Electromagnetism/Optics

3 lecture hours 3 lab hours 4 credits
Course Description
This course is the calculus based continuation of PH 2010 . The purpose of this subject is to acquaint the students with the fundamental laws of electricity, magnetism, and optics. Particular topics include: electrostatic vector fields, scalar potential, capacitance and dielectrics, energy and force in electrostatic systems, current, resistance and electromotive force, magnetic fields and forces, electromagnetic waves, laws of reflection and refraction, geometrical optics and image formation, and interference and diffraction. PH 2020 is taught in an integrated lecture-lab format. (prereq: PH 2010  or PH 2010A  or EE 3051B , CH 200  or CH 200A  or CH 200B  or CH 2100H  or CH 310 , MA 137  or MA 137A  or MA 1410H ) (coreq: MA 231  or MA 1420H  or MA 3501 )
Course Learning Outcomes
Upon successful completion of this course, the student will be able to:
  • Understand the concept of electric charge and be able to determine the electric forces between, and the electric field produce by, point charges
  • Determine the electric fields produced by distributed charges and conductors
  • Determine the motion of point charges and electric dipoles in an electric field
  • Understand electric potential (V) in terms of potential energy as well as in relationship to the electric field
  • Understand the relationships between C, V, E, Q and U for a capacitor
  • Make basic electric circuit calculations and relate the macroscopic concepts (V, I, R etc.) to the corresponding field and microscopic concepts (E, j, “rho” etc.)
  • Determine the magnetic forces and torques on moving charges and currents
  • Determine the magnetic fields produced by currents as well as by magnetic material
  • Apply the concept of changing magnetic flux to determine the induced emf
  • Determine the basic properties of electromagnetic waves
  • Apply the concepts of geometrical optics
  • Apply the concepts of wave optics
  • Use graphical analysis to analyze the results of an experiment
  • Do a proper uncertainty analysis

Prerequisites by Topic
  • College level algebra
  • Units, exponential notation and prefixes
  • Vector algebra - dot and cross products
  • Differentiation and integration of polynomial, trigonometric, exponential and logarithmic functions
  • College level calculus base mechanics-kinematics, dynamics and energy concepts
  • Be familiar with the atomic picture of material - Periodic Table of Elements
  • College level lab experience - techniques, safety, and report writing

Course Topics
  • Introduction (1 hour)
  • Coulomb’s and Gauss’s laws (10 hours)
  • Electric potential and potential energy (4 hours)
  • Capacitance (4 hours)
  • Current, resistance, and electromotive force (5 hours)
  • Magnetic forces and fields (12 hours)
  • Electromagnetic induction (6 hours)
  • Maxwell’s equations and electromagnetic waves (3 hours)
  • Geometrical optics (6 hours)
  • Interference, diffraction and polarization (5 hours)
  • Tests (4 hours)

Laboratory Topics
  • Instrumentation, Ohm’s law
  • Electrostatic Acceleration and Deflection of Electrons
  • Qualitative Field and Equipotential plots for various electrode configurations
  • Quantitative determination of the field between Concentric Cylinders
  • Capacitance
  • Resistance and Resistivity
  • Magnetic Deflection of Electrons
  • Magnetic Field produced by Magnets and Currents
  • Electromagnetic Induction
  • Mirrors and Lenses
  • Interference, Diffraction, and the Grating Spectrometer

Coordinator
Anders Schenstrom



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