Chapter 25. Capacitance

Similar documents
Chapter 25. Capacitance

PH 222-2A Spring 2015

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

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

Energy Stored in Capacitors

= (series) Capacitors in series. C eq. Hence. Capacitors in parallel. Since C 1 C 2 V 1 -Q +Q -Q. Vab V 2. C 1 and C 2 are in series

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

Chapter 26. Capacitance and Dielectrics

Chapter 26. Capacitance and Dielectrics

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

Chapter 26. Capacitance and Dielectrics

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

Chapter 24: Capacitance and Dielectrics

2014 F 2014 AI. 1. Why must electrostatic field at the surface of a charged conductor be normal to the surface at every point? Give reason.

Definition of Capacitance

Capacitance and Dielectrics

Chapter 1 The Electric Force

Chapter 4. Electrostatic Fields in Matter

Phys102 Second Major-161 Zero Version Coordinator: Dr. Naqvi Monday, December 12, 2016 Page: 1

Chapter 24 Capacitance and Dielectrics

ENGR 2405 Chapter 6. Capacitors And Inductors

Physics 202, Exam 1 Review

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

Chapter 24: Capacitance and Dielectrics

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

7. A capacitor has been charged by a D C source. What are the magnitude of conduction and displacement current, when it is fully charged?

Capacitance. Chapter 21 Chapter 25. K = C / C o V = V o / K. 1 / Ceq = 1 / C / C 2. Ceq = C 1 + C 2

Physics 202, Exam 1 Review

Physics 169. Luis anchordoqui. Kitt Peak National Observatory. Thursday, February 22, 18

PHYSICS. Electrostatics

F = Q big = c) The electric potential in a certain region of space can be described by the equation: 16y2 (1 + z 2 ) V (x, y, z) = 10x

Electricity. Revision Notes. R.D.Pilkington

Chapter 24: Capacitance and Dielectrics

Capacitors (Chapter 26)

Friday July 11. Reminder Put Microphone On

CHAPTER 18 ELECTRIC POTENTIAL

ELECTRO MAGNETIC FIELDS

Chapter 26. Capacitance and Dielectrics

PHY102 Electricity Course Summary

Exam 2 Practice Problems Part 1

NAME Write you name also on the back page of this exam.

Sharpen thinking about connections among electric field, electric potential difference, potential energy

iclicker A device has a charge q=10 nc and a potential V=100V, what s its capacitance? A: 0.1 nf B: 1nF C: 10nF D: F E: 1F

Electric Field of a uniformly Charged Thin Spherical Shell

CLASS XII WB SET A PHYSICS

Chapter 2: Capacitors And Dielectrics

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

Capacitance, Resistance, DC Circuits

INDIAN SCHOOL MUSCAT FIRST TERM EXAMINATION PHYSICS

A) 1, 2, 3, 4 B) 4, 3, 2, 1 C) 2, 3, 1, 4 D) 2, 4, 1, 3 E) 3, 2, 4, 1. Page 2

LESSON 2 PHYSICS NOTES

Do not fill out the information below until instructed to do so! Name: Signature: Section Number:

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

Consider a point P on the line joining the two charges, as shown in the given figure.

Chapter Electrostatic Potential and Capacitance

Physics (

PHYSICS - CLUTCH CH 24: CAPACITORS & DIELECTRICS.

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

AP Physics C. Electricity - Term 3

Capacitance and Dielectrics

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

Gurgaon TOPIC: ELECTROSTATIC Assignment 1 (2018)

Physics 420 Fall 2004 Quiz 1 Wednesday This quiz is worth 6 points. Be sure to show your work and label your final answers.

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

Chapter 24 Capacitance and Dielectrics

PHYS208 RECITATIONS PROBLEMS: Week 2. Gauss s Law

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

Capacitors. Gauss s law leads to

F 13. The two forces are shown if Q 2 and Q 3 are connected, their charges are equal. F 12 = F 13 only choice A is possible. Ans: Q2.

Gauss s Law. q 4. The Gaussian surfaces do not have to be spheres. Constant flux through any closed surface.

W05D1 Conductors and Insulators Capacitance & Capacitors Energy Stored in Capacitors

Electric Flux and Gauss Law

Chapter 2: Capacitor And Dielectrics

PRACTICE EXAM 1 for Midterm 1

PH Physics 211 Exam-2

Magnetic Force on a Moving Charge

AP Physics Study Guide Chapter 17 Electric Potential and Energy Name. Circle the vector quantities below and underline the scalar quantities below

13 - ELECTROSTATICS Page 1 ( Answers at the end of all questions )

Physics 222, Spring 2010 Quiz 3, Form: A

Gauss s Law. q 4. The Gaussian surfaces do not have to be spheres. Constant flux through any closed surface.

AP Physics C Electricity & Magnetism Mid Term Review

Capacitance and capacitors. Dr. Loai Afana

ISLAMABAD ACADEMY PHYSICS FOR 10TH CLASS (UNIT # 15)

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

Lecture 20. March 22/24 th, Capacitance (Part I) Chapter , Pages

ELECTROSTATIC CBSE BOARD S IMPORTANT QUESTIONS OF 1 MARKS

Class 5 : Conductors and Capacitors

Chapter 29. Electric Potential: Charged Conductor

Electrostatic Potential and Capacitance Examples from NCERT Text Book

Capacitance and Dielectrics

Physics 102 Spring 2007: Final Exam Multiple-Choice Questions

Phys102 Second Major-181 Zero Version Coordinator: Kunwar, S Monday, November 19, 2018 Page: 1

Today in Physics 122: capacitors

Capacitors. HPP Activity 68v1. Charge Inside the Body A Close Look at Cell Membranes

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.

Calculus Relationships in AP Physics C: Electricity and Magnetism

Capacitance. PHY2049: Chapter 25 1

Can current flow in electric shock?

AP Physics C. Magnetism - Term 4

Transcription:

Chapter 25 Capacitance

25.2: Capacitance:

25.2: Capacitance: When a capacitor is charged, its plates have charges of equal magnitudes but opposite signs: q+ and q-. However, we refer to the charge of a capacitor as being q, the absolute value of these charges on the plates. The charge q and the potential difference V for a capacitor are proportional to each other: The proportionality constant C is called the capacitance of the capacitor. Its value depends only on the geometry of the plates and not on their charge or potential difference. The SI unit is called the farad (F): 1 farad (1 F)= 1 coulomb per volt =1 C/V.

25.2: Capacitance: Charging a Capacitor: The circuit shown is incomplete because switch S is open; that is, the switch does not electrically connect the wires attached to it. When the switch is closed, electrically connecting those wires, the circuit is complete and charge can then flow through the switch and the wires. As the plates become oppositely charged, that potential difference increases until it equals the potential difference V between the terminals of the battery. With the electric field zero, there is no further drive of electrons. The capacitor is then said to be fully charged, with a potential difference V and charge q.

25.3: Calculating the Capacitance: To relate the electric field E between the plates of a capacitor to the charge q on either plate, we use Gauss law: Here q is the charge enclosed by a Gaussian surface and is the net electric flux through that surface. In our special case in the figure, in which A is the area of that part of the Gaussian surface through which there is a flux. the potential difference between the plates of a capacitor is related to the field E by If V is the difference V f -V i, Here,

25.3: Calculating the Capacitance, A Cylindrical Capacitor : As a Gaussian surface, we choose a cylinder of length L and radius r, closed by end caps and placed as is shown. It is coaxial with the cylinders and encloses the central cylinder and thus also the charge q on that cylinder.

25.3: Calculating the Capacitance, A Spherical Capacitor:

25.3: Calculating the Capacitance, An Isolated Sphere: We can assign a capacitance to a single isolated spherical conductor of radius R by assuming that the missing plate is a conducting sphere of infinite radius. The field lines that leave the surface of a positively charged isolated conductor must end somewhere; the walls of the room in which the conductor is housed can serve effectively as our sphere of infinite radius. To find the capacitance of the conductor, we first rewrite the capacitance as: Now letting b, and substituting R for a,

Example, Charging the Plates in a Parallel-Plate Capacitor:

25.4: Capacitors in Parallel and in Series: When a potential difference V is applied across several capacitors connected in parallel, that potential difference V is applied across each capacitor. The total charge q stored on the capacitors is the sum of the charges stored on all the capacitors. Capacitors connected in parallel can be replaced with an equivalent capacitor that has the same total charge q and the same potential difference V as the actual capacitors.

25.4: Capacitors in Parallel and in Series: When a potential difference V is applied across several capacitors connected in series, the capacitors have identical charge q. The sum of the potential differences across all the capacitors is equal to the applied potential difference V. Capacitors that are connected in series can be replaced with an equivalent capacitor that has the same charge q and the same total potential difference V as the actual series capacitors.

Example, Capacitors in Parallel and in Series:

Example, Capacitors in Parallel and in Series:

Example, One Capacitor Charging up Another Capacitor:

25.5: Energy Stored in an Electric Field: Suppose that, at a given instant, a charge q has been transferred from one plate of a capacitor to the other. The potential difference V between the plates at that instant will be q /C. If an extra increment of charge dq is then transferred, the increment of work required will be, The work required to bring the total capacitor charge up to a final value q is This work is stored as potential energy U in the capacitor, so that, This can also be expressed as:

25.5: Energy Stored in an Electric Field: Energy Density In a parallel-plate capacitor, neglecting fringing, the electric field has the same value at all points between the plates. Thus, the energy density u that is, the potential energy per unit volume between the plates should also be uniform. We can find u by dividing the total potential energy by the volume Ad of the space between the plates. But since(c =e 0 A/d), this result becomes However, (E=-DV/Ds), V/d equals the electric field magnitude E. Therefore.

Example, Potential Energy and Energy Density of an Electric Field:

25.6: Capacitor with a Dielectric: A dielectric, is an insulating material such as mineral oil or plastic, and is characterized by a numerical factor k, called the dielectric constant of the material. Some dielectrics, such as strontium titanate, can increase the capacitance by more than two orders of magnitude. The introduction of a dielectric also limits the potential difference that can be applied between the plates to a certain value Vmax, called the breakdown potential. Every dielectric material has a characteristic dielectric strength, which is the maximum value of the electric field that it can tolerate without breakdown.

Example, Work and Energy when a Dielectric is inserted inside a Capacitor:

25.7: Dielectrics, an Atomic View: 1. Polar dielectrics. The molecules of some dielectrics, like water, have permanent electric dipole moments. In such materials (called polar dielectrics), the electric dipoles tend to line up with an external electric field as in Fig. 25-14. Since the molecules are continuously jostling each other as a result of their random thermal motion, this alignment is not complete, but it becomes more complete as the magnitude of the applied field is increased (or as the temperature, and thus the jostling, are decreased).the alignment of the electric dipoles produces an electric field that is directed opposite the applied field and is smaller in magnitude. 2. Nonpolar dielectrics. Regardless of whether they have permanent electric dipole moments, molecules acquire dipole moments by induction when placed in an external electric field. This occurs because the external field tends to stretch the molecules, slightly separating the centers of negative and positive charge.

25.8: Dielectrics and Gauss Law: For the situation of Fig. 25-16a, without a dielectric, the electric field between the plates can be found using Gauss s Law. We enclose the charge q on the top plate with a Gaussian surface and then apply Gauss law. If E 0 represents the magnitude of the field, we have In Fig. 25-16b, with the dielectric in place, we can find the electric field between the plates (and within the dielectric) by using the same Gaussian surface. Now the surface encloses two types of charge: It still encloses charge +q on the top plate, but it now also encloses the induced charge q on the top face of the dielectric. The charge on the conducting plate is said to be free charge because it can move if we change the electric potential of the plate; the induced charge on the surface of the dielectric is not free charge because it cannot move from that surface. The effect of the dielectric is to weaken the original field E 0 by a factor of k: Since

25.8: Dielectrics and Gauss Law: 1. The flux integral now involves ke, not just E. (The vector is sometimes called the electric displacement, D. The above equation can be written as: 2. The charge q enclosed by the Gaussian surface is now taken to be the free charge only. The induced surface charge is deliberately ignored on the right side of the above equation, having been taken fully into account by introducing the dielectric constant k on the left side. 3. e 0 gets replaced by ke 0. We keep k inside the integral of the above equation to allow for cases in which k is not constant over the entire Gaussian surface.

Example, Dielectric Partially Filling a Gap in a Capacitor:

Example, Dielectric Partially Filling a Gap in a Capacitor, cont.:

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