Welcome to Physics 202 Today’s Topics  The Physics 202 Team  Course Formality and Overview  Ch : Electric Charge, Coulomb's Law Text: Giancoli, Physics for Scientists and Engineers, 4th ed., Volume II. Physics 202 Homepage

Meet the Physics 202 Team  Faculty (lectures): ☻Prof. Lisa Everett Research: theoretical high energy physics Office hrs: M 4:35 or by appointment, 5215 CH, ☻Prof. Bruce Mellado Research: experimental high energy physics Office hrs: by appointment, 4223 CH,

Meet the Physics 202 Team  Teaching Assistants (labs, discussion): ☺ Pankoj Gindodia ☺ Shusaku Horibe ☺ Trevor Irwin ☺ Robert Lindner ☺ Jason McCuistion ☺ Paul McGuirk ☺ Valerie Plaus ☺ Yongyan Rao ☺ Jared Schmitthenner ☺ Koki Takasaki Office hours: in 2307 CH (starting Jan 28). Schedule:

Physics 202 Course Composition  Lectures: TR 8:50 am (Lec. 1), 9:55 am (Lec. 2) Honors: F 8:50 am (w/ Physics 208)  Labs: mandatory! Each missing lab = grade pt. 10 labs total. grading: weekly lab quizzes, 2 lab reports  Discussion Sections: 2/week. grading: discussion quizzes (5 total during the semester), participation,…  Exams: 3 midterms + final (word problem format)  Homework: ~10 problems/week, web-based Online homework system: MasteringPhysics tutorial + end-of-chapter problems (not aligned with our text yet)

Exams and Exam Policy Exam Dates –Midterms: (5:30-7 PM, rooms TBA) Exam 1: M Feb 18 Exam 2: R Mar 13 Exam 3: M Apr 14 –Final: M May 12 (5:05-7:05 PM, rooms TBA), Cumulative If you have an academic conflict with the exam dates, inform the professors and your TA ASAP (at latest: 2 weeks before the exam period) so that we can accommodate you. (Exam policy details on course website)

The challenges of Physics 202: Topics: electromagnetism, waves, optics. Many new concepts, less familiar/intuitive topics, more mathematical rigor e.g. vector calculus (line integrals, surface integrals, gradients) How to Succeed … 1.Do the required reading before lecture -the lectures assume you are familiar with the material 2.Keep up -- don’t get behind!! 3.Ask questions early if you don’t understand things -in lecture ask!! …also consult outside class: in discussion section and office hours. 4.Problem solving develops and tests your conceptual understanding -- as well as your computational skill - this is how you can demonstrate what you have learned…

Physics 201, 202 and 249 Light and Optics Electromagnetism Classical Mechanics Laws of motion Force, Energy, Momentum,… Oscillation and Waves Relativity Atomic Structure Sub-Sub-Atomic: Elementary Particles Cosmology Many-Atoms: Molecules, solids Sub-Atomic: Nuclear Physics Modern Classical Quantum theory

Building blocks: Physics 201 Mechanics: Motion and Force Newton’s laws of motion (“Classical” view) Conservation laws: energy, momentum, angular momentum (“modern” view) Newton’s Law of Universal Gravitation. We will build on these concepts in Physics 202! We expect that you know the following basic concepts: uniformly accelerated motion, work-kinetic energy theorem, potential energy, static equilibrium, circular motion, simple harmonic motion, torque and rotational motion,… Mechanics Gravitation

Physics 202 Electromagnetism –Electric force, field, and potential: stationary charges (electrostatics) –Current, capacitance & resistance –Magnetic force and field: steady currents (magnetostatics) –Time-dependent fields: Maxwell’s equations –Electromagnetic waves, wave motion, superposition –DC and AC Circuits Light and Optics –Light as rays: Geometric optics, imaging –Light as electromagnetic waves, interference

Chapter 21: Electric Charge and Field Today:  Electric charges  Fundamental units of charge  Conductors and insulators  Electrostatic force: Coulomb’s Law Thursday:  Electric Field  Calculating electric fields from charge distributions  Motion of charged particle in external electric field  Please read Ch. 21 before Thursday’s lecture

Electric Charge Like signs repelOpposite signs attract Charges do not have to be in contact to interact Two types!

Properties of Electric Charge  2 types: positive or negative*  SI Unit: Coulomb (C). 1 C= chg of 6.24x10 18 protons  Building blocks of matter:  Electric charge is quantized: q=  N e (e =1.602x C)  Electric charge of isolated system is conserved * neutral objects: no charge or equal amount of + and - Charge (C)Mass (kg) Electron -e =-1.602x x Proton +e =+1.602x x Neutron01.675x10 -27

Conductors v. Insulators Electroscope (next lab) charge also by induction! Conductors (metals…): charges free to move Insulators (glass, plastic, rubber…): Consider how charge is carried on macroscopic objects. In Physics 202, we are concerned with only 2 types: charges NOT free to move (phenomenon: polarization)

Neutral metal Positively charged rod (too few electrons) Less positively charged rod Positively charged metal electron flow Charging by conduction (touching)

Charging conductors by Induction Charging by induction requires no contact with the object inducing the charge a) We start with a neutral metallic sphere b) The rod does not touch the sphere. The electrons in the neutral sphere are redistributed charged rubber rod a) b)

Charging by Induction, 2 If the sphere is grounded: electrons can leave the sphere through the ground wire (earth: infinite storage conductor) If ground wire is removed, there is still a net positive charge on the sphere -- a positive charge has been induced. When the rod is removed, electrons will redistribute in the sphere.

Coulomb’s Law Electric Force b/w 2 stationary point charges: (Coulomb’s Law) Coulomb Constant: k = 8.987x10 9 Nm 2 /C 2 = 1/(4  0 )  0 : permitivity of free space = 8.85x C 2 /Nm 2 Attractive (opp sign charges), repulsive (like sign charges)  Four fundamental forces: Strong > Electromagnetic > Weak >> Gravitation

Coulomb’s Law: Vector Form 2 charges: force on q 2 by q 1 principle of linear superposition >2 charges: force on charge i F 12 F 21 F 12 F 21 Examples (board): 21.13, 21.18, 21.20