Chapter 29. Electric Potential: Charged Conductor

Similar documents
Chapter 26. Capacitance and Dielectrics

Look over. examples 1, 2, 3, 5, 6. Look over. Chapter 25 section 1-8. Chapter 19 section 5 Example 10, 11

Definition of Capacitance

Parallel Plate Capacitor, cont. Parallel Plate Capacitor, final. Capacitance Isolated Sphere. Capacitance Parallel Plates, cont.

Chapter 26. Capacitance and Dielectrics

Chapter 26. Capacitance and Dielectrics

Chapter 26. Capacitance and Dielectrics

Chapter 24: Capacitance and Dielectrics

Chapter 24: Capacitance and Dielectrics. Capacitor: two conductors (separated by an insulator) usually oppositely charged. (defines capacitance)

Capacitance. PHY2049: Chapter 25 1

General Physics II. Conducting concentric spheres Two concentric spheres of radii R and r. The potential difference between the spheres is

Electricity and Magnetism. Capacitance

Capacitance and Dielectrics. Chapter 26 HW: P: 10,18,21,29,33,48, 51,53,54,68

Capacitors (Chapter 26)

Capacitance and capacitors. Dr. Loai Afana

Chapter 2: Capacitor And Dielectrics

EX. Potential for uniformly charged thin ring

Chapter 2: Capacitors And Dielectrics

Chapter 24. Capacitance and Dielectrics Lecture 1. Dr. Armen Kocharian

W05D1 Conductors and Insulators Capacitance & Capacitors Energy Stored in Capacitors

General Physics (PHY 2140)

Today s agenda: Capacitors and Capacitance. You must be able to apply the equation C=Q/V.

Chapter 25. Capacitance

Homework. Reading: Chap. 29, Chap. 31 and Chap. 32. Suggested exercises: 29.17, 29.19, 29.22, 29.23, 29.24, 29.26, 29.27, 29.29, 29.30, 29.31, 29.

CAPACITANCE. Capacitor. Because of the effect of capacitance, an electrical circuit can store energy, even after being de-energized.

AP Physics C - E & M. Slide 1 / 39 Slide 2 / 39. Slide 4 / 39. Slide 3 / 39. Slide 6 / 39. Slide 5 / 39. Capacitance and Dielectrics.

Capacitors. Example 1

Physics 212. Lecture 8. Today's Concept: Capacitors. Capacitors in a circuits, Dielectrics, Energy in capacitors. Physics 212 Lecture 8, Slide 1

Physics Electricity and Magnetism Lecture 06 - Capacitance. Y&F Chapter 24 Sec. 1-6

Chapter 16. Electric Energy and Capacitance

Electronics Capacitors

Chapter 6 Objectives

Electric Potential. Capacitors (Chapters 28, 29)

Chapter 18. Circuit Elements, Independent Voltage Sources, and Capacitors

Capacitor Construction

Where C is proportionally constant called capacitance of the conductor.

University Physics (PHY 2326)

Capacitors and more. Lecture 9. Chapter 29. Physics II. Course website:

Capacitors and more. Lecture 9. Chapter 29. Physics II. Course website:

Agenda for Today. Elements of Physics II. Capacitors Parallel-plate. Charging of capacitors

Danger High Voltage! Your friend starts to climb on this... You shout Get away! That s High Voltage!!! After you save his life, your friend asks:

Chapter 16. Electric Energy and Capacitance

Chapter 1 The Electric Force

Physics (

Physics Electricity and Magnetism Lecture 06 - Capacitance. Y&F Chapter 24 Sec. 1-6

iclicker A metal ball of radius R has a charge q. Charge is changed q -> - 2q. How does it s capacitance changed?

Physics Electricity & Op-cs Lecture 8 Chapter 24 sec Fall 2017 Semester Professor

Agenda for Today. Elements of Physics II. Capacitors Parallel-plate. Charging of capacitors

Chapter 19 Electric Potential and Electric Field

Physics Jonathan Dowling. Physics 2102 Lecture 7 Capacitors I

Capacitance and Dielectrics

Capacitors. Lecture 10. Chapter 26. My Capacitance is limited. PHYS.1440 Lecture 10 Danylov. Department of Physics and Applied Physics

AP Physics C. Electric Circuits III.C

Potentials and Fields

Chapter 24: Capacitance and Dielectrics

(3.5.1) V E x, E, (3.5.2)

Chapter 24 Capacitance and Dielectrics

This work is licensed under a Creative Commons Attribution-Noncommercial-Share Alike 4.0 License.

Electric Potential Energy Chapter 16

Capacitor: any two conductors, one with charge +Q, other with charge -Q Potential DIFFERENCE between conductors = V

Capacitors Diodes Transistors. PC200 Lectures. Terry Sturtevant. Wilfrid Laurier University. June 4, 2009

Energy Stored in Capacitors

Physics 219 Question 1 January

Chapter 24 Capacitance and Dielectrics

Potential from a distribution of charges = 1

Electric Potential Energy Conservative Force

CHAPTER 6. Inductance, Capacitance, and Mutual Inductance

Electric Field of a uniformly Charged Thin Spherical Shell

Designing Information Devices and Systems I Fall 2018 Lecture Notes Note Introduction to Capacitive Touchscreen

PH213 Chapter 24 Solutions

Exam 1 Solutions. The ratio of forces is 1.0, as can be seen from Coulomb s law or Newton s third law.

Chapter 24: Capacitance and Dielectrics

which checks. capacitance is determined entirely by the dimensions of the cylinders.

Physics 212. Lecture 7. Conductors and Capacitance. Physics 212 Lecture 7, Slide 1

CAPACITORS / CAPACITANCE ECET11

Class 5 : Conductors and Capacitors

Example 1 Physical Sizes of Capacitors

COLLEGE PHYSICS Chapter 19 ELECTRIC POTENTIAL AND ELECTRIC FIELD

Chapter 25. Capacitance

4) A 3.0 pf capacitor consists of two parallel plates that have surface charge densities of 1.0

PHY101: Major Concepts in Physics I. Photo: J. M. Schwarz

Chapter 28. Direct Current Circuits

Chapter 16 Electrical Energy Capacitance. HW: 1, 2, 3, 5, 7, 12, 13, 17, 21, 25, 27 33, 35, 37a, 43, 45, 49, 51

Physics 112 Homework 2 (solutions) (2004 Fall) Solutions to Homework Questions 2

TEST 2 3 FIG. 1. a) Find expression for a capacitance of the device in terms of the area A and d, k 1 and k 2 and k 3.

Electric Potential Practice Problems

Chapter 14 CAPACITORS IN AC AND DC CIRCUITS

Physics / Higher Physics 1A. Electricity and Magnetism Revision

C = V Q. To find the capacitance of two conductors:

Version 001 CIRCUITS holland (1290) 1

shown in Fig. 4, is initially uncharged. How much energy is stored in the two capacitors after the switch S is closed for long time?

The Basic Capacitor. Dielectric. Conductors

The Capacitor. +q -q

The Basic Capacitor. Water Tower / Capacitor Analogy. "Partnering With Our Clients for Combined Success"

Reading: Electrostatics 3. Key concepts: Capacitance, energy storage, dielectrics, energy in the E-field.

Phys 2025, First Test. September 20, minutes Name:

Physics Lecture: 16 MON 23 FEB Capacitance I

Chapter 17. Potential and Capacitance

Electricity. Revision Notes. R.D.Pilkington

[1] (b) Fig. 1.1 shows a circuit consisting of a resistor and a capacitor of capacitance 4.5 μf. Fig. 1.1

Transcription:

hapter 29 Electric Potential: harged onductor 1

Electric Potential: harged onductor onsider two points (A and B) on the surface of the charged conductor E is always perpendicular to the displacement ds Therefore, E ds = 0 Therefore, the potential difference between A and B is also zero!!!! 2

Electric Potential: harged onductor The potential difference between A and B is zero!!!! Therefore V is constant everywhere on the surface of a charged conductor in equilibrium ΔV = 0 between any two points on the surface The surface of any charged conductor is an equipotential surface Because the electric field is zero inside the conductor, the electric potential is constant everywhere inside the conductor and equal to the value at the surface 3

Electric Potential: onducting Sphere: Example 0 E 0 Electric field inside conducting sphere is 0 r E ke r 2 Electric field outside sphere B V 0 B r V V Eds Edr Edr k dr k B A e 2 e r A r r r The same expression for potential (outside sphere) as for the point charge (at the center of the sphere). 4

Electric Potential: onducting Sphere: Example 0 E 0 Electric field inside conducting sphere is 0 r B E ke r 2 Electric field outside sphere R B B B V V Eds Edr Edr Edr Edr B A e R A A A A k dr k 2 r e R The electric potential is constant everywhere inside the conducting sphere V 0 5

Electric Potential: onducting Sphere: Example Vr ke r for r > R V sphere ke R for r < R The potential of conducting sphere!! 6

onducting Sphere: Example What is the potential of conducting sphere with radius 0.1 m and charge 1μ? 6 9 10 Vsphere ke 9 10 90000V R 0.1m 7

hapter 30 apacitance 8

apacitors apacitors are devices that store electric charge A capacitor consists of two conductors These conductors are called plates When the conductor is charged, the plates carry charges of equal magnitude and opposite directions A potential difference exists between the plates due to the charge A A B B A B - the charge of capacitor V V V - a potential difference of capacitor 9

apacitors A capacitor consists of two conductors A conductors (plates) Plate A has the SAME potential at all points because this is a conductor. B Plate B has the SAME potential at all points. So we can define the potential difference between the plates: V V V A B 10

apacitance of apacitor A V The SI unit of capacitance is the farad (F) = /V. B apacitance is always a positive quantity The capacitance of a given capacitor is constant and determined only by geometry of capacitor The farad is a large unit, typically you will see microfarads ( μf) and picofarads (pf) 11

apacitor: Spherical apacitor V No electric field outside of the capacitor (because the total charge is 0). The field inside the capacitor is due to small sphere. The potential difference is only due to a small sphere: 1 1 V ke b a The capacitance: ab V k b a e 12

apacitor: Isolated Sphere V b a a The capacitance: b a ab ab a V k ba k b k e e e 13

apacitor: Parallel Plates E 0 E σ ε E 0 1 2 σ 0 E σ0 V 0 V σ x ε V σ h ε σ S E 0 0 The potential difference: σ V h h ε εs 0 The capacitance: V 0εS h 14

apacitor: harging Each plate is connected to a terminal of the battery The battery establishes an electric field in the connecting wires This field applies a force on electrons in the wire just outside of the plates The force causes the electrons to move onto the negative plate This continues until equilibrium is achieved The plate, the wire and the terminal are all at the same potential At this point, there is no field present in the wire and there is no motion of electrons Battery- produce the fixed voltage the fixed potential difference 15

Energy Stored in a apacitor Assume the capacitor is being charged and, at some point, has a charge q on it The work needed to transfer a small charge q from one plate to the other is equal to the change of potential energy q dw Vdq dq If the final charge of the capacitor is, then the total work required is q q B A W q dq 0 2 2 16

Energy Stored in a apacitor W q dq 0 2 2 The work done in charging the capacitor is equal to the electric potential energy U of a capacitor V 2 1 1 ( ) 2 U V V 2 2 2 This applies to a capacitor of any geometry 17

Energy Stored in a apacitor: Application 2 1 1 ( ) 2 U V V 2 2 2 One of the main application of capacitor: capacitors act as energy reservoirs that can be slowly charged and then discharged quickly to provide large amounts of energy in a short pulse V 18

hapter 30 apacitance and Electrical ircuit 19

Electrical ircuit A circuit diagram is a simplified representation of an actual circuit ircuit symbols are used to represent the various elements Lines are used to represent wires The battery s positive terminal is indicated by the longer line 20

Electrical ircuit onducting wires. In equilibrium all the points of the wires have the same potential 21

Electrical ircuit V The battery is characterized by the voltage the potential difference between the contacts of the battery V In equilibrium this potential difference is equal to the potential difference between the plates of the capacitor. Then the charge of the capacitor is V V If we disconnect the capacitor from the battery the capacitor will still have the charge and potential difference V 22

Electrical ircuit V V V V If we connect the wires the charge will disappear and there will be no potential difference V 0 23

apacitors in Parallel V 2 V 1 All the points have the same potential All the points have the same potential V The capacitors 1 and 2 have the same potential difference V Then the charge of capacitor 1 is 1 1V The charge of capacitor 2 is 2 2V 24

apacitors in Parallel The total charge is V 2 V 2 2 1 2 V V ( ) V 1 2 1 2 V V 1 1 1 This relation is equivalent to the following one V eq eq 1 2 eq V 25

apacitors in Parallel The capacitors can be replaced with one capacitor with a capacitance of eq The equivalent capacitor must have exactly the same external effect on the circuit as the original capacitors V eq 26

apacitors The equivalence means that V eq V 27

apacitors in Series V 1 V 2 2 1 V V V1V2 28

apacitors in Series V 1 1 V 2 2 The total charge is equal to 0 1 2 V 1 V 2 2 1 V V1V2 V eq 1 2 1 1 1 eq 1 2 V eq 1 2 1 2 29

apacitors in Series An equivalent capacitor can be found that performs the same function as the series combination The potential differences add up to the battery voltage 30

Example in parallel eq 12 13 4 eq 1 2 6 eq 1 2 8 in series in parallel eq 1 2 1 2 8 8 88 4 in parallel 31

V 32

Energy Stored in a apacitor Assume the capacitor is being charged and, at some point, has a charge q on it The work needed to transfer a small charge q from one plate to the other is equal to the change of potential energy q dw Vdq dq If the final charge of the capacitor is, then the total work required is q q B A W q dq 0 2 2 33

Energy Stored in a apacitor W q dq 0 2 2 The work done in charging the capacitor is equal to the electric potential energy U of a capacitor V 2 1 1 ( ) 2 U V V 2 2 2 This applies to a capacitor of any geometry 34

Energy Stored in a apacitor: Application 2 1 1 ( ) 2 U V V 2 2 2 One of the main application of capacitor: capacitors act as energy reservoirs that can be slowly charged and then discharged quickly to provide large amounts of energy in a short pulse V 35

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback