Download General Physics for Engineering II PHYS 191

Qatar University
College of Arts and Sciences
Department of Math, Stat & Physics
General Physics II Syllabus, Fall 2011
COURSE INFORMATION:
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Course Title : General Physics for Engineering II, PHYS
Prerequisite: PHYS 191 & PHYS 192
In Class Hours : 4
Mon: 09:30-10:45:00
Credit Hours : 3
Wed: 09:30-10:45:00
Class Time :
Thu: 13:00-13:50:00
193
Class Location : Women's College of Science D215
INSTRUCTOR
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Name: Dr.Abouzeid Shalaby
E-mail: [email protected]
Office Location: C 211
Sun: 10:00-11:00
Office Hours:
Tue: 10:00-12:00
Thu: 10:00-11:00
Or by appointment
TEXTBOOK
Wed:
Physics for Scientists
and10AMEngineers with Modern Physics
09:11AM
and Mastering Physics, by Douglas C. Giancoli, Pearson.
Or by appointment
REFERENCES
1. Physics for Scientists and Engineers, by Serway and Jewett, Brooks Cole.
2. Physics for Scientists and Engineers, by Randle Knight, Addison Wesley.
Additional Sources
Online Sources
 http://ocw.mit.edu/courses/physics/8-02-physics-ii-electricity-andmagnetism-spring-2007/class-slides/
 http://demonstrations.wolfram.com/topic.html?topic=Electrostatic
s&limit=20
EVALUATION POLICY
Three major exams will be given:
 First Exam:
20%,Saturday November 19th , 2011, 10:00 –12:00
 Second Exam:
25%, Saturday December 17th , 2011, 10:00 –12:00
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Final Exam:
35%, Saturday , January 147th , 2011, 10:00 – 12:00
Assignments
10%
Quizzes:
10%
2+ points as a bonus for performance in the class.
GRADES
Grades will be assigned based on the following scale:
Percent grade 90 -100 85 - 89 80 - 84 75 -79 70 - 74
A
B+
B
C+
C
Letter grade
4.0
3.5
3.0
2.5
2.0
Earned Points
65 - 69
D+
1.5
60 - 64
D
1.0
below 60
F
0.0
INSTRUCTIONS & REGULATIONS
1. Using Mobile phones during lectures or exams is prohibited. Turn off your cell
phone during class, any one uses mobile will be asked to leave the lecture room.
2. Students are expected to attend all classes, if they do not show up for more than
25% of the classes, they fail the course. There are no grades for attendance.
3. Quizzes and assignments have no make-ups, so try not to miss any.
4. Students are expected to participate actively in the class.
5. Check your e-mail regularly.
6. Be responsible for all class activities, announcements, and assignments when you
miss a class.
7. Do not hesitate to see me if you have any question.
8. Prior to class, look over the section that will be covered.
9. Regularly check the BLACKBOARD site at: http://mybb.qu.edu.qa/
10. It is highly recommended that the students make every effort to attend an assigned
exam because there is no an intention to arrange or schedule a make-up exam. In
case of certified personal emergency, the student must contact the instructor
immediately and right prior to the exam.
COURSE CONTENTS
1. ELECTRIC CHARGE AND ELECTRIC FIELD
2. GAUSS’S LAW
3. ELECTRIC POTENTIAL
4. CAPACITANCE, DIELECTRICS, ELECTRIC ENERGY
5. ELECTRIC CURRENTS AND RESISTANCE
6. DC CIRCUITS
7. MAGNETISM
8. SOURCES OF MAGNETIC FIELD
9. ELECTROMAGNETIC INDUCTION AND FARADAY’S LAW
10. INDUCTANCE, ELECTROMAGNETIC OSCILLATIONS, AND AC CIRCUITS
11. MAXWELL’S EQUATIONS AND ELECTROMAGNETIC WAVES
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Course Objectives
OB 1 Demonstrate knowledge and understanding of the fundamental laws and theorems of Electrostatics
and Magnetostatics.
OB 2 Strengthen the considerate of the basic principles and laws of Electrodynamics.
OB 3 Develop a basic conceptual knowledge of the fundamental of Electromagnetic Waves.
LEARNING OUTCOMES
Course Learning Outcomes
LO 1 Explain the origin of electromagnetic phenomena in view of modern atomic theory.
Define and calculate the basic physical quantities of electrostatics for the case of simple static
LO 2 charge distribution; namely: Coulomb’s force, electrostatic field, electric Flux, electrostatic
potential, voltage, and capacitance.
LO 3 Represent the electric and magnetic field graphically for various charge distributions.
LO 4 Draw the equipotential lines of electric potential for various simple charge configurations.
Define and calculate the basic physical quantities of Magnetostatics for the case of simple steady
LO 5
current distribution; namely magnetic force, magnetic field, and magnetic dipole moment.
LO 6 Describe and explain the effects due to the electric and magnetic properties of materials.
Classify matter according to its response to external magnetic field: Ferromagnetism,
LO 7
Paramagnetism, and Diamagnetism.
Define and determine the basic quantities of 1D steady electrodynamics; specifically: current,
LO 8
current density, voltage, Resistance, resistivity, conductivity, emf, and power.
LO 9 Explain the formation of Eddy’s current in a conducting materials.
LO 10 Illustrate the phenomena of electromagnetic induction and self and mutual inductance.
state the fundamental laws and theorems of Electricity & Magnetism in their integral and
LO 11 differential forms , namely: Coulomb’s law, Gauss’s law, Ohm’s Law , Kirchhoff’s Rules
,Lorentz force law, Biot-Savart law, Ampere’s circuital theorem, Faraday’s law, and Lenz’s law.
Apply the knowledge of the fundamental laws and theorems of Electricity & Magnetism in
LO 12
solving problems involving simple dynamic charge configurations.
LO 13 Analyze simple DC and AC circuits.
State the fundamental equations that govern all electromagnetic phenomena, Maxwell’s four
LO 14
equations.
LO 15 State the basic properties of electromagnetic waves.
LO 16 Explain the fundamental laws of geometrical optics.
DELIVERY METHOD
We will use different types of teaching methods including:
1. Presentation explaining material.
2. Problem solving.
3. Discussion - actively involving students in learning by asking questions that
provoke thinking and verbal response.
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LEARNING RESOURCES AND MEDIA
1. Lectures as PPT will be used to present the subject
2. In class, we will use white board and/or head projector to explain mathematical
formulas
3. Blackboard will be used frequently
DETAILED TIME SCHEDULE
Week
Section
1
21—1 Static Electricity; Electric Charge and Its Conservation 21—2 Electric Charge in the Atom
21—3 Insulators and Conductors 21—4 Induced Charge; the Electroscope 21—5 Coulomb’s Law
21—6 The Electric Field 21—7 Electric Field Calculations for Continuous Charge Distributions
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21—8 Field Lines 21—9 Electric Fields and Conductors 21—10 Motion of a Charged Particle in an
Electric Field 22—1 Electric Flux 22—2 Gauss’s Law 22—3 Applications of Gauss’s Law
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23—1 Electric Potential Energy and Potential Difference 23—2 Relation between Electric Potential
and Electric Field 23—3 Electric Potential Due to Point Charges 23—4 Potential Due to Any Charge
Distribution 23—5 Equipotential Surfaces 23—7 E Determined from V 23—8 Electrostatic Potential
Energy; the Electron Volt
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24—1 Capacitors 24—2 Determination of Capacitance 24—3 Capacitors in Series and Parallel
24—4 Electric Energy Storage 24—5 Dielectrics
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25—1 The Electric Battery 25—2 Electric Current 25—3 Ohm’s Law: Resistance and Resistors
25—4 Resistivity 25—5 Electric Power 25—6 Power in Household Circuits
25—7 Alternating Current 25—8 Microscopic View of Electric Current: Current Density and Drift
Velocity
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26-1 EMF and Terminal Voltage 26-2 Resistors in Series and in Parallel 26-3 Kirchoff’s Rules
26-4 EMFs in Series and in Parallel; Charging a Battery 26-5 Circuits Containing Resistor and
Capacitor (RC Circuits)
First Exam - Saturday November 19th , 2011, 10:00 –12:00
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27-1 Magnets and Magnetic Fields 27-2 Electric Currents Produce Magnetic Fields 27-3 Force on an
Electric Current in a Magnetic Field
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27-4 Force on an Electric Charge Moving in a Magnetic Field 27-5 Torque on a Current Loop;
Magnetic Dipole Moment
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28-1 Magnetic Field Due to a Straight Wire 28-2 Force between Two Parallel Wires 28-3 Definitions
of the Ampere and the Coulomb 28-4 Ampere’s Law
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28-5 Magnetic Field of a Solenoid and a Toroid 28-6 Biot-Savart Law- 28-7 Magnetic materials–
Ferromagnetism
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29-1 Induced EMF 29-2 Faraday’s Law of Induction; Lenz’s Law 29-3 EMF Induced in a Moving
Conductor
Second Exam-Saturday December 1 7th , 2011, 10:00 – 12:00
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13
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30-1 Mutual Inductance 30-2 Self-Inductance 30-3 Energy Stored in a Magnetic Field 30-4 LR
Circuits 30-5 LC Circuits and Electromagnetic Oscillations
30-6 LC Oscillations with Resistance (LRC Circuit) 30-7 AC Circuits with AC Source 30-8 LRC Series
AC Circuit 30-9 Resonance in AC Circuits
31-1 Changing Electric Fields Produce Magnetic Fields; Ampere’s Law and Displacement Current
31-2 Gauss’s Law for Magnetism 31-3 Maxwell’s Equations 31-4 Production of Electromagnetic
Waves
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Final Exam-Saturday , January 14th , 2012, 10:00 – 12:00
 Course Matrix (Matrix of Objectives and Outcomes)
OBJECTIVES
Demonstrate
knowledge and
understanding of the
fundamental laws and
theorems of
Electrostatics and
Magnetostatics.
Strengthen the
considerate of the basic
principles and laws of
Electrodynamics.
Develop a basic
conceptual knowledge
of the fundamental of
Electromagnetic
Waves.
LEARNING
OUTCOMES
Assessment Tools
LO 1, LO 2, LO3, LO 4, LO
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Assignments, Quizzes, , Exams
LO 6, LO 7, LO 8, LO10
Assignments, Quizzes, Exams
Assignments, Quizzes, Exams
LO 9, LO11, LO12
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