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12/16/14 x DATE REQUIRED COURSE ELECTIVE COURSE Math/Science x DIVISION NEW COURSE REVISION LAKE LAND COLLEGE Course Information Form COURSE NUMBER PHY141 SEM CR HRS 4.00 LT HRS TITLE 3.00 University Physics II LAB HRS 3.00* SOE HRS COURSE PCS# 0.00 ECH 5.25 (Assigned by Administration) Prerequisites: PHY 140 with grade of 'C' or higher, MAT 242 Catalog Description (40 Word Limit): This course is a study of heat, electricity, and magnetism for students in physics, engineering, chemistry, and mathematics. List the Major Course Segments (Units) Temperature, Heat and First Law Contact Lt Hrs. 7 Contact Lab Hrs. 8 Entropy and Second Law 5 4 Kinetic Theory of Gases 4 4 Elementary Concepts of Charge 1 2 Electric Fields - Gauss’s Law - Electric Potential 8 6 Capacitors and Dielectrics 2 3 Elementary Circuits 4 6 The Magnetic Field and Ampere’s Law 5 4 Faraday’s Law, Inductance, Oscillatory Circuits 5 5 AC Circuits and a Summary of Maxwell’s Equation 4 3 *Lab hours are experiments, demonstrations, discussions and exams EVALUATION: Quizzes Lab Work x x Exams Projects x Oral Pres. Comp Final Textbook: Title Fundamentals of Physics (Extended) Author Halliday, Resnick, & Walker Publisher John Wiley & Sons Volume/Edition 9th Edition Copyright Date 2011 x Papers Other homework Major Course Segment Temperature - Zeroth Law of Thermodynamics The Celsius and Fahrenheit Scale Linear, Area, and Volume Expansion Conduction, Convection and Radiation Heat Capacity and Latent Heat The Equation of State Van der Waals Gas Work of a Gas The First Law of Thermodynamics Isochoric, Isobaric, Isothermal, and Adiabatic Processes Cyclic Processes The Second Law of Thermodynamics and Heat Engines The Carnot Cycle Refrigerators and Heat Pumps The Absolute Temperature Scale and the Third Law of Thermodynamics Entropy: A State Variable Entropy Changes for Irreversible Processes The Ideal-Gas Model Pressure and Molecular Motion Temperature and Molecular Motion The Equipartition-of-Energy Theorem Monatomic, Polyatomic, and Diatomic Gas Models The Maxwell Sped-Distribution Function Mean Free Path Electric charge including continuous Charge Distributions Coulomb's Law The Electric Field Point Charge Distributions Continuous Charge Distributions Electric Field Lines Hours 15 9 8 8 Learning Outcomes Various problematic situations will be measured. This includes tests, lab reports, quizzes, and computer outcomes. The Electric Dipole in a Uniform Electric Field Electric Flux Gauss’s Law Gaussian Surfaces Coulomb’s Law from Gauss’s Law Electric Potential Energy The Electric Potential Electric Potential Change Due to a Uniform Electric Field Electric Potential Change in a Nonuniform Electric Field Computing the Electric Potential from a Charge Distribution Point-Charge Distributions Continuous Charge Distributions Computing the Electric Field from the Electric Potential The Relation Between V and E Equipotential Surfaces Capacitance Capacitors in Parallel, Series, and in Networks Energy Storage in a Capacitor Dielectrics Electric Current and Current Density Resistivity and Resistance Temperature Dependence of Resistivity Energy Dissipation Electromotive Force Resistors in Series, Parallel and in Networks Multiple-Loop Circuits: Kirchhoff’s Rules Potential Difference, Current, and Resistance Measurements Voltmeters Ammeters The Wheatstone Bridge The Potentiometer RC Circuits The Magnetic Field Moving Charges in Uniform Magnetic Fields The Hall Effect 9 5 4 6 Force on a Current-Carrying Conductor Current-Carrying Loops in a Uniform Magnetic Field The Magnetic Dipole Moment The Biot-Savart Law Ampère’s Law The Solenoid The Toroid Magnetic Flux and Gauss’s Law for Magnetism Faraday's Law Lenz's Law Induced Electric Fields Eddy Currents The Displacement Current Inductors LR Circuits Energy and the Magnetic Field LC Circuits Diamagnetic, Paramagnetic, and Ferromagnetic Phases Diamagnetism Paramagnetism Ferromagnetism RLC AC Circuits The Root-Mean-Square Potential and Current Power and Resonance in AC Circuits Transformers Filter Circuits Summary of Maxwell’s Equations 8 3 6 2 7 Course Outcomes: At the successful completion of this course, students will be able to: Apply to the First Law of Thermodynamics. Understand that heat engines are limited by the Second Law of Thermodynamics and that there is a simple formula for heat engine efficiency. Analyze simple circuits (Ohm’s Law, Kirchoff’s Laws) as well as the way circuit elements like resistors and capacitors work. Apply the ‘Ed’ rule for electric fields and voltage. Understand, and apply in applications, how a charged particle moves in an electric and/or magnetic field; how an electric and/or magnetic field is created. Understand the four Maxwell equations in their integral format and utilize in appropriate situations. To wit: Gauss’ Law of electric fields; the ‘no-charge’ Gauss’ Law of magnetic fields, Ampere’s Law, and Faraday’s Law. Analyze the basic operation of an electric motor and an electric generator.