PHYS 2086
Xiaobing Zhou, Assistant Professor of Geophysics

Electricity, Magnetism & Motion


Lecture (PHYS 3036 - 02): Monday/Wednesday/Friday 10:00 am - 10:50 am at ELC 203

Instructor: Dr Xiaobing Zhou, Email: xzhou@mtech.edu, Tel: 496-4350

Office Hours: M/W/F 4:00pm -5:00pm, ELC 304

Textbook (required):
Serway, A. S. & J. W. Jewett, Jr., Physics for Scientists and Engineers, (Chapters 23-34), 6th Edition, Thomson-Brooks/Cole publishers, 2004.

Main references (recommended):

  1. Electricity and Magnetism, online textbook by Benjamin Crowell,
  2. Electricity and Magnetism 1
  3. Electricity and Magnetism 2
  4. Molecular Expressions: Electricity and Magnetism
  5. HyperPhysics Concepts
  6. Bloomfield, Louis A., How Things Work, The Physics of Everyday Life,2nd Ed., Wiley, 2001.
  7. de Armond, John, "Ground Fault Interrupters", http://personal.cha.bellsouth.net/cha/j/o/johngd/files/rv/gfi.pdf, posted 11/00, Link
  8. Craford, M. George, Holonyak, Nick, and Kish, Frederick, "In Pursuit of the Ultimate Lamp", Scientific American 284, 62, February 2001.

Course Description:
This is the third course in the calculus-based physics sequence. Basic physical concepts, laws, properties, nature, and implication for modern sciences of electricity, magnetism, and electromagnetic waves are covered. Basic electronic elements - resistor, capacitor, inductaor, etc. are introduced. Basic circuit analysis is covered. The development of problem-solving skills fundamental to students of all branches of engineering will be emphasized Corequisite: Math 2236 (Differential Equations).


Prerequisites:
Undergraduate level PHYS 1046 (General Physics - Mechanics) Minimum Grade of D and Undergraduate level MATH 2510 (Calculus III) Minimum Grade of D and/or Undergraduate level MATH 2236 (Minimum Grade of D)

Objectives:

1) To develop an understanding of the basic concepts, laws, properties, and physical processes in electric field, magnetic field, basic circuit analysis, and application;
2) To develop the skills to solve physical problems in electricity and magnetic using calculus.

Homework & Quizzes:

Homework will generally be assigned on Wednesday and due the following Wednesday; otherwise, just follow the announcement in classes or the specified due date on the homework sheet. Answer keys to the homework questions will generally be given in the assignments. No more than that. Homework will be put in the "Homework" subdirectory under "Course Documents" directory in Blackboard for this course. Group discussing in doing homework is permitted but copying answers from others is prohibited. Copied homework will be graded as “zero” or “F”. No homework will be dropped in calculating your course grade.  Late homework will not be accepted absolutely. Not all questions in each homework assignment will be graded. Graded questions in each homework assignment will total 100 pts.

Quizzes:

Basically, a quiz will be given each week, but may be on an irregular basis. The content of each quiz will generally within that covered in the previous week. Of all the quizzes, the two that you got the lowest grades will be dropped in calculating your final course grade. Each quiz will total 100 pts. The final grade for the quizzes will the average of all your quiz grades with the two lowest dropped out.

Grade Policy:

Your final grade for the course will depend on your active participation, ability to understand and apply the various concepts, laws, physical process and calculus in solving electric and magnetic problems. The final grade of the course will be determined approximately as follows:

Attendance:      10 %
Homework:      20%
Quizzes:            25%
Midterm exam:  20%
Final exam:        25% 

The instructor reserves the right to give extra credit to active participation and demonstrated interest and capability. Grading scale observes: A=(92,100], A-=[90, 92], B+=(87, 90), B=[83, 87], B-=[80, 83), C+=(77, 80), C=[73, 77], C-=[70, 73), D+=(67, 70), D=[63, 67], D-=[60, 63), F=[0, 60). [ or ] means inclusive, ( or ) means exclusive. Also: A= 4.0, A-=3.7, B+=3.3, B=3.0, B-=2.7, C+=2.3, C=2.0, C-=1.7, D+=1.3, D=1.0, D-=0.7, F=0.

Tentative Schedule:

Date  Day Lecture No.  Topic  Reading
Assignment
 Homework
(Due each Wednesday)
Jan-14-08
Jan-16-08
Jan-18-08
 Monday
Wednesday
Friday
 Lecture 1 
Lecture 2
Lecture 3
 Electric charge: properties, conductor, and induction (23.1-23.2)
Coulomb's law and electric field (23.3-23.5)
Field line and particle motion (23.6-23.7)
 23.1-3
23.3-7
24.1-2 		 
Jan-21-08
Jan-23-08
Jan-25-08 
Monday
Wednesday
Friday
 Holiday
Lecture 4
Lecture 5
Electric flux and Gauss's law (24.1)
Application of Gauss's law (24.2-3)
24.3
24.4-5
Homework 1

Jan-28-08
Jan-30-08
Feb-01-08
Monday
Wednesday
Friday 		Lecture 6
Lecture 7
Lecture 8
 Electrostatic equilibrium and derivation of Gauss's law (24.4-24.5)
Electrical potential (25.1)
Electrical potential, potential energy, and electrical field (25.2-4)
 25.1-2
25.3-4
25.5-7
Homework 2
Feb-04-08
Feb-06-08
Feb-08-08
 Monday
Wednesday
Friday 		Lecture 9
Lecture 10
Lecture 11
 Electrical potential and Millikan experiment (25.5-25.7)
Applications of electrostatics (25.8)
Capacitance (26.1-26.2, 26.5)
 25.8
26.1-2,5
26.3-4
Homework 3

Feb-11-08
Feb-13-08
Feb-15-08
Monday
Wednesday
Friday 		Lecture 12
Lecture 13
Lecture 14
 Capacitor connection and energy storage (26.3-26.4)
Electric pole and dielectrics (26.6-26.7)
Electric current (27.1-27.2)
 26.6-7
27.1-2
27.3-4
Homework 4
Feb-18-08
Feb-20-08
Feb-22-08
Monday
Wednesday
Friday 		Lecture 15
Lecture 16
Lecture 17
 Electric resistance (27.3-4)
Conduction (27.5)
Electrical power and applications (27.6)
 27.5
27.6
28.1-2
Homework 5
Feb-25-08
Feb-27-08
Feb-29-08
 Monday
Wednesday
Friday		 Lecture 18
Lecture 19
Lecture 20
 Electromotive force and resistor connection (28.1-28.2)
Kirchhoff's laws and RC circuits (28.3-28.4)
Electrical meters and safety (28.5-28.6)
 28.3-4
28.5-6
29.1-3
Homework 6
Mar-03-08
Mar-05-08
Mar-07-08
Monday
Wednesday
Friday		 Lecture 21
Lecture 22
Lecture 23
 Magnetic fields, forces, and torque (29.1-29.3)
Motion of charged particle in magnetic field and applications (29.4-29.5)
Hall effect and Biot-Savart law (29.6, 30.1)
 29.4-5
29.6,30.1
30. 2-3
Homework 7
Mar-10-08
Mar-12-08
Mar-14-08  		Monday
Wednesday
Friday
 Lecture 24
Mid-term Exam
Lecture 25
 Magnetic and current interaction (30.2-30.3)
Content for mid-term includes Chapters 23-29.
Magnetic generation and magnetic flux (30.4-30.5) 		30.4-5
23-28
30.6-7 		Homework 8
Mar-17-08
Mar-19-08
Mar-21-08
Monday
Wednesday
Friday		 Spring Break




Mar-24-08
Mar-26-08
Mar-28-08
 Monday
Wednesday
Friday		 Lecture 26
Lecture 27
Lecture 28
 Gauss's law and Ampère's law in magnetism (30.6-30.7)
Magnetism in matter and geomagnetism (30.8-30.9)
Faraday's law and motional EMF (31.1-31.2)
 30.8-9
31.1-2
31.3-4
Homework 9
Mar-31-08
Apr-02-08
Apr-04-08  		Monday
Wednesday
Friday		 Lecture 29
Lecture 30
Lecture 31
 Lenz's law, induced EMF and electrical field (31.3-31.4)
Generator and motor (31.5)
Eddy current and Maxwell's equations (31.6-31.7)
 31.5-7
32.1-3
Homework 10
Apr-07-08
Apr-09-08
Apr-11-08
Monday
Wednesday
Friday 		Lecture 32
Lecture 33
Lecture 34
 Inductance, RL circuits and energy storage in inductor (32.1-32.3)
Mutual inductance (32.4)
oscillation in LC circuits RLC circuits (32.5-32.6)
 32.4-5
32.6
33.1-2
Homework 11
Apr-14-08
Apr-16-08
Apr-18-08
Monday
Wednesday
Friday		 Lecture 35
Lecture 36
Lecture 37
 Power sources and resistors in AC circuits (33.1-33.2)
Inductors (33.3)
Capacitors in AC circuits and Phasor (33.4-33.5)
 33.3-4
33.5-7
33.8-9
Homework 12
Apr-21-08
Apr-23-08
Apr-25-08
 Monday
Wednesday
Friday		 Lecture 38
Lecture 39
Lecture 40
 Series RLC circuits: phase, impedance, power, and resonance (33.6-33.7)
Transformer, power transmission, rectifier and filter (33.8-33.9)
Maxwell's equations, Hertz's apparatus, and plane EM waves (34.1-34.2)
 34.1-2
34.3-4
34.5-6
Homework 13
Apr-28-08
Apr-30-08
May-02-08
 Monday
Wednesday
Friday		 Lecture 41
Lecture 42
Lecture 43
 Energy, momentum, and radiation pressure of EM waves (34.3-34.4)
EM wave generation and EM spectrum (34.5-34.6)
Course Review
none
30.1-34.6
Homework 14

May-08-08

 Thursday Final Exam
3:00 pm - 5:00 pm, ELC 203


 
 


Other references (just for those who are interested and want to dig indepth  in electricity and magnetism):
  1. Baseden, Alan, Lightning Destruction, Atlanta Journal, July 16, 1991.
  2. Blackwood, O H, Kelly, W C, and Bell, R M, General Physics, 4th Edition, Wiley, 1973.
  3. Diefenderfer, James, Principles of Electronic Instrumentation, 2nd Ed. , W.B. Saunders, 1979.
  4. Diefenderfer, James and Holton, Brian, Principles of Electronic Instrumentation, 2nd Ed. ,Saunders College Publ., 1994.
  5. Ewell, George W., Radar Transmitters, McGraw-Hill, 1981.
  6. Floyd, Thomas L., Electric Circuit Fundamentals, 2nd Ed., Merrill, 1991
  7. Floyd, Thomas L., Electronic Devices 3rd Ed., Merrill, 1992
  8. Giancoli, Douglas C., Physics, 4th Ed, Prentice Hall, (1995).
  9. Halliday & Resnick, Fundamentals of Physics, 3E, Wiley 1988
  10. Halliday, Resnick & Walker, Fundamentals of Physics, 4th Ed, Extended, Wiley 1993
  11. Horowitz, Paul and Hill, Winfred,The Art of Electronics, Cambridge University Press, 1980
  12. Jackson, J. D., Classical Electrodynamics, Wiley (1975).
  13. Jones, Edwin R (Rudy) and Childers, Richard L, Contemporary College Physics, Addison-Wesley, 1990. A well-illustrated non-calculus introductory physics text.
  14. Jung, Walter, IC Op-Amp Cookbook, Howard Sams, 1981
  15. Ladbury, Ray, "Geodynamo Turns Toward a Stable Magnetic Field", Physics Today 49, Jan 96, pg 17.
  16. Mims, Forrest M, Op Amp IC Circuits, Engineer's Mini-Notebook, Cat. No. 276-5011A, Radio Shack 1985
  17. Mims, Forrest M, Digital Logic Circuits, Radio Shack 1985
  18. Mims, Forrest M., Getting Started in Electronics, Radio Shack, 1983
  19. Mims, Forrest M., 555 Timer IC Circuits, 3rd Ed, Engineer's Mini-Notebook, Radio Shack Cat. No. 276-5010A, 1992
  20. Mims, Forrest, Optoelectronic Circuits: Engineers Mini-Notebook, Radio Shack Cat. No. 276-5012, 1986. Small notebook with practical details and sketches of circuit applications.
  21. Nave & Nave, Physics For the Health Sciences, 3rd Ed, W. B. Saunders, 1985
  22. Ohanian, Hans, Physics, 2nd Ed. Expanded, Norton, 1985.
  23. Reitz, J., Milford, F. and Christy, R., Foundations of Electromagnetic Theory, 4th Ed, Addison-Wesley, 1993.
  24. Rohlf, J. W., Modern Physics from a to Z0, Wiley 1994
  25. Schwarz, W. M., Intermediate Electromagnetic Theory, Wiley, 1964.
  26. Scott, W. T., The Physics of Electricity and Magnetism, Wiley, 1959.
  27. Sears, F. W., Zemansky, M. W., Young, H. D., University Physics, 6th Ed., Addison-Wesley, 1982.
  28. Serway & Faughn, College Physics, Saunders College, 1985
  29. Simpson, Robert E., Introductory Electronics for Scientists and Engineers, 2nd Ed., Allyn and Bacon, 1987
  30. Skilling, H. H., Fundamentals of Electric Waves, 2nd Ed, Wiley, 1948
  31. Summit Electrical, searchable database for technical information about electrical products, http://www.summit.com/site map/search.htm .
  32. Tipler, Paul A., Physics for Scientists and Engineers, 3rd Ed, Extended, Worth Publishers, 1991
  33. Tocci, Ronald J., Digital Systems, 5th Ed, Prentice-Hall, 1991.
  34. Uman, Martin, Everything you always wanted to know about lightning but were afraid to ask, Saturday Review, May 13, 1972. Also text Lightning, McGraw Hill, 1969.
  35. Williams,E R, The Electrification of Thunderstorms, Scientific American Nov 88, p88.
  36. Young, Hugh D., University Physics, 8th Ed., Addison-Wesley, 1992.
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Last Updated: January 10, 2008