Green sheet Online HW assignments Practice Problems Course overview See course website www.physics.sjsu.edu/Becker/physics51 OVERVIEW C 2012 J. Becker.

Slides:

Advertisements

Similar presentations

Electric Charges and Electric Fields

Advertisements

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

16.6 Solving Problems Involving Coulomb’s Law and Vectors Vector addition review:

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

Electric Charge and Electric Field Electric Charge and Electric Field

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

Fisica Generale - Alan Giambattista, Betty McCarty Richardson Copyright © 2008 – The McGraw-Hill Companies s.r.l. 1 Chapter 16: Electric Forces and Fields.

Electricity Chapter 19. Introduction n One of the oldest problem in physics n phenomena related to electric charge n deals with -interactions between.

Preview Objectives Properties of Electric Charge Transfer of Electric Charge Chapter 16 Section 1 Electric Charge.

Copyright © 2012 Pearson Education Inc. PowerPoint ® Lectures for University Physics, Thirteenth Edition – Hugh D. Young and Roger A. Freedman Lectures.

Cutnell/Johnson Physics 8th edition Reading Quiz Questions

Copyright © 2008 Pearson Education Inc., publishing as Pearson Addison-Wesley PowerPoint ® Lectures for University Physics, Twelfth Edition – Hugh D. Young.

Chapter 21 Electric Field and Coulomb’s Law (again) Coulomb’s Law (sec. 21.3) Electric fields & forces (sec & -6) Vector addition C 2009 J. F. Becker.

Green sheet HW assignments (tentative) Course overview See OVERVIEW C 2009 J. Becker.

Chapter 21 Electric Field and Coulomb’s Law (again) Electric fields and forces (sec. 21.4) Electric field calculations (sec. 21.5) Vector addition (quick.

2. 2s /eo between, ±s /eo outside. 3. zero both between and outside.

1 From Last Time… Total internal reflection Object Image Lenses and imaging.

Electrification - the process that produces electric charges on an object. Electrostatic charge - a charge confined to an object and not moving. Static.

Chapter 1 Electric charge and electric forces Chapter 1.

Lecture 2 Properties of Electric Charges Insulators and Conductors Coulomb’s Law Electric Field Problem Solving Strategy.

Physics 2102 Introduction to Electricity, Magnetism and Optics Physics 2102 Gabriela González Charles-Augustin de Coulomb ( )

Chapter 23 Electric Fields. Intro The electromagnetic force between particles is one of the four fundamental forces of nature. We will begin by discussing.

ELECTRIC FORCES AND ELECTRIC FIELDS

Chapter 19 Electric Charges, Forces, and Fields. Units of Chapter 19 Electric Charge Insulators and Conductors Coulomb’s Law The Electric Field Electric.

Electrostatics. Electric Charge and Electric Field.

Lecture 5 Potential Difference Capacitance Combinations of Capacitors

Electrical Energy and Capacitance Concept of potential difference and potential Potential and potential energy for point charges Potentials and charged.

Chapter 16 Electric Charge and Electric Field © 2008 Giancoli, PHYSICS,6/E © Electronically reproduced by permission of Pearson Education, Inc.,

Chapter 16 Electric Charge and Electric Field. Units of Chapter 16 Static Electricity; Electric Charge and Its Conservation Electric Charge in the Atom.

Introduction to Electrostatics Unit 14, Presentation 1.

Electric Forces and Electric Fields

Chapter 19 Electric Forces and Electric Fields Electric Charges There are two kinds of electric charges Called positive and negative Negative.

The study of electrical charges at rest

My Chapter 16 Lecture Outline.

Electric Charge and Electric Field

Electric Forces and Fields

Electric Field Physics Overview Properties of Electric Charges Charging Objects by Induction Coulomb’s Law The Electric Field Electric Field Lines.

Ch Electricity I. Electric Charge  Atoms and Charge  Conductors  Insulators  Static Electricity  Electric Discharge.

Physics 213 General Physics Lecture 1. Today Syllabus Administrative details Class Overview Introduction to Electricity and Magnetism Static electric.

1 Physics 8.02T For now, please sit anywhere, 9 to a table.

From Last Time… Lenses and image formation Optical Instruments p q

Green sheet Online HW assignments Practice Problems Course overview See course website OVERVIEW C 2012 J. Becker.

Electric Forces and Electric Fields

Lecture A Fundamentals and Background. Charge “Charge” is the basic quantity in electrical circuit analysis Fundamental charge quantity is the charge.

Static Electricity.

Chapter 16 Electric Charge and Electric Field © 2002, B.J. Lieb Giancoli, PHYSICS,5/E © Electronically reproduced by permission of Pearson Education,

Electric Charge Electric Fields

Electric Charges, Forces and Fields

© 2010 Pearson Education, Inc. Conceptual Physics 11 th Edition Chapter 22: ELECTROSTATICS Electrical Forces and Charges Conservation of Charge Coulomb’s.

Week 1 - S2 Feb. 15 – 20, 2016 Fields 4.1.Electric Fields

Electric Charge and Electric Field

Static Electricity. All objects contain electrical charges. These charges come from three subatomic particles: ProtonsElectronsNeutrons.

Electrostatics Wenny Maulina. Electric charge Protons have positive charge Electrons have negative charge Opposite signs attract Similar signs repel.

Bell Ringer Using only the PVC, move the soda can, but you cannot touch the can with the PVC or blow on the can. Explain how you did it.

Static Electricity, Electric Forces, Electric Fields.

Static Electricity, Electric Forces, Electric Fields.

Static Electricity What are the fundamental particles and how do they interact?

Electricity & Magnetism Chapter 7 Section 1 Electric Charge.

HPH102: Introduction and Electrostatics Miss L. G. Thwala.

Electric Charge and Electric Field

Lecture 1: Mostly electric charges and fields

Chapter 21 Electric Field and Coulomb’s Law (again)

Electric Charge and Electric Field

Electric Forces and Electric Fields

Electric Charge and Electric Field

Electrostatics.

Properties of Electric Charge

Electrostatics.

ELECTRICAL CHARGE Ch. 32.

Presentation transcript:

Green sheet Online HW assignments Practice Problems Course overview See course website OVERVIEW C 2012 J. Becker

PHYSICS 51 GREEN SHEET Front side: Course outline Back side: Reading assignment and problems

3 slides printed on a page

Chapter 21A Electric Field and Coulomb’s Law Electric charge (sec. 21.1) Conductors, insulators, and induced charge (sec. 21.2) Coulomb’s Law (sec. 21.3) Electric field lines (sec. 21.6) C 2012 J. Becker

Learning Goals - we will learn: The nature of electric charge. How objects become electrically charged. How to use Coulomb’s Law to calculate the electric force between charges. How to calculate the electric field caused by electric charges. How to use the idea of electric field lines to visualize electric fields.

Electric charge Protons have positive charge Electrons have negative charge Opposite signs attract Similar signs repel Electric field – used to calculate force between charges C 2012 J. Becker

Photocopiers are amazing devices. They use electric charge to hold fine dust (toner) in patterns until the pattern may be transferred to paper and made permanent with heat.

LITHIUM (Li) ELEMENT Atom: electrically neutral 3 protons and 3 elec. Positive ion: missing one electron so net charge is positive Negative ion: has added electron so net charge is negative

A positive charge and a negative charge attract each other. Two positive charges (or two negative charges) repel each other.

Figure 21.5 Electric forces in action

Figure 21.1a

Figure 21.1b

Figure 21.1c

Figure 21.6a Copper is a good conductor of electricity; Glass and nylon are good insulators

Figure 21.6b

Figure 21.6c

CHARGING A METAL SPHERE BY INDUCTION Charges are free to move in a conductor but are tightly bound in an insulator. The earth (“ground”) is a large conductor having many free charges.

POLARIZED insulator

In an insulator the charges can move slightly (called polarization of the insulator). A piece of paper is attracted to a charged comb because the positive charges are closer to the negatively charged comb (in the upper figure). CHARGED COMB ATTRACTS A PIECE OF PAPER

e - PAPER DISPLAY (Kindle, i - PAD, etc.) wikipedia.org/wiki/Electronic_paper Scheme of an electrophoretic display.

e - PAPER DISPLAY (Kindle, i - PAD, etc.) wikipedia.org/wiki/Electronic_paper Each capsule contains an oily solution containing black dye (the electronic ink), with numerous white titanium dioxide (white) particles suspended within. The white particles are slightly negatively charged. Applying a negative charge to the surface electrode repels the particles to the bottom of local capsules, forcing the black dye to the surface and giving the capsule, or pixel, a black appearance. Reversing the voltage has the opposite effect - the particles are forced to the surface, giving the pixel a white appearance.

An uncharged conductor can attract the charge imparted to paint droplets. Excess charges can flow to or from “ground” -e Car door

Figure 21.2 The imaging drum is aluminum coated with selenium, which changes from an insulator to a conductor when illuminated with light. LASER PRINTER USES CHARGED TONER

FORCE between two charges is given by Coulomb’s Law: | F | = k | Q q o | / r 2

We can use our notion of the gravitational field to form the concept of an ELECTRIC FIELD (E) Recall force between two masses: F = m g g is the gravitational field (9.8 m/sec 2 ) | F | = G | M m | / r 2 The force between two charges Q and q o is given by: F = q o E | F | = k | Q q o | / r 2

Coulomb’s Law: | F | = k | Q q o | / r 2 Rearranged: | F | = | q o [k Q/r 2 ] | Gives us: F = q o E where the electric field E is: | E | = | k Q / r 2 |

ELECTRIC FIELD LINES START AND END AT ELECTRIC CHARGES An electric charge is surrounded by an electric field just as a mass is surrounded by a gravitational field.

Electric field and equipotential lines are perpendicular to each other In Lab #2 a voltmeter is used to measure the equipotential lines (in Volts) in order to determine the magnitude and direction of the electric field lines.

Forces on electron beam in a TV tube (CRT) F = Q E and F = m g (vector equations)

TV tube with electron-deflecting charged plates (orange) F = Q E

see Review

Vectors Review (See Chapter 1) Used extensively throughout course INTRODUCTION: see Ch. 1 C 2012 J. Becker

Vectors are quantities that have both magnitude and direction. An example of a vector quantity is velocity. A velocity has both magnitude (speed) and direction, say 60 miles per hour in a DIRECTION due west. (A scalar quantity is different; it has only magnitude – mass, time, temperature, etc.)

A vector may be composed of its x- and y- components as shown.

Note: The dot product of two vectors is a scalar quantity. The scalar (or dot) product of two vectors is defined as

The vector (or cross) product of two vectors is a vector where the direction of the vector product is given by the right-hand rule. The MAGNITUDE of the vector product is given by:

Figure 21.14

PROFESSIONAL FORMAT