© 2012 Pearson Education, Inc. The two conductors a and b are insulated from each other, forming a capacitor. You increase the charge on a to +2Q and increase.

Slides:



Advertisements
Similar presentations
Capacitors.
Advertisements

Chapter 24 Capacitance.
Physics 2113 Lecture: 06 WED 01 OCT
Chapter 24 Capacitance, Dielectrics, Electric Energy Storage
Physics 2112 Unit 8: Capacitors
Electric Potential and Field
Chapter 23: Electrostatic Energy and Capacitance
©1997 by Eric Mazur Published by Pearson Prentice Hall Upper Saddle River, NJ ISBN No portion of the file may be distributed, transmitted.
LECTURE 11 Pick up reading quiz #2 lecture notes for Lecture 11 Course questionnaire Pick up reading quiz #2 lecture notes for Lecture 11 Course questionnaire.
You reposition the two plates of a capacitor so that the capacitance doubles. There is vacuum between the plates. If the charges +Q and –Q on the two plates.
Physics 2102 Capacitors Gabriela González. Summary (last class) Any two charged conductors form a capacitor. Capacitance : C= Q/V Simple Capacitors: Parallel.
Unit 2 Day 3: Electric Energy Storage Electric potential energy stored between capacitor plates Work done to add charge to the capacitor plates Energy.
Fall 2008Physics 231Lecture 4-1 Capacitance and Dielectrics.
Example: a parallel plate capacitor has an area of 10 cm 2 and plate separation 5 mm. 300 V is applied between its plates. If neoprene is inserted between.
Halliday/Resnick/Walker Fundamentals of Physics 8th edition
CAPACITORS SLIDES BY: ZIL E HUMA. OBJECTIVES CHARGING OF THE CAPACITORS DISCHARGING OF THE CAPACITORS DIELECTRIC MATERIALS FACTORS EFFECTING THE VALUES.
Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.
1 Capacitance and Dielectrics Chapter 27 Physics chapter 27.
Chapter 25: Capacitance What are “ capacitor ” s? What do we use them for (in real life) What do we want to know about a capacitor: 1.Capacitance 2.Charge.
Lecture 8 Friday January 30 Capacitors and Review.
Copyright © 2012 Pearson Education Inc. PowerPoint ® Lectures for University Physics, Thirteenth Edition – Hugh D. Young and Roger A. Freedman Lectures.
Capacitance Physics Department, New York City College of Technology.
Capacitors in series: Capacitors in parallel: Capacitors Consider two large metal plates which are parallel to each other and separated by a distance.
Capacitance and dielectrics(sec. 24.1) Capacitors in series and parallel (sec. 24.2) Energy storage in capacitors and electric field energy(sec. 24.3)
24 volts + - When fully charged which of these three capacitors holds the largest quantity of charge, Q? 2)B 3)C 4)all are the same Which of these three.
Capacitance and dielectrics(sec. 24.1) Capacitors in series and parallel (sec. 24.2) Energy storage in capacitors and electric field energy(sec. 24.3)
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Electric potential energy Electric potential Conservation of energy Chapter.
© 2012 Pearson Education, Inc. { Chapter 23 Electric Potential (cont.)
© 2012 Pearson Education, Inc. { Chapter 30 Inductance.
Chapter 26 Capacitance and Dielectrics. Concept Question 1.
Capacitors.
Physics for Scientists and Engineers, 6e
ConcepTest 25.1 Capacitors
Electric Potential. Electrostatic Potential Energy and Potential Difference The electrostatic force is conservative – potential energy can be defined.
© 2012 Pearson Education, Inc. A small, circular ring of wire (shown in blue) is inside a larger loop of wire that carries a current I as shown. The small.
Capacitance and Dielectrics
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Electric potential energy Electric potential Conservation of energy Capacitors.
GENERAL PHYSICS LECTURE Chapter 26 CAPACITANCE AND DIELECTRICS Nguyễn Thị Ngọc Nữ PhD: Nguyễn Thị Ngọc Nữ.
Capacitor An element that stores charge when a voltage is applied
Capacitors, Batteries. Capacitors Create a difference in Potential based upon how much charge is stored V = q/C (V) C : Capacitance C = k ε o A /d k :
111/16/2015 ELECTRICITY AND MAGNETISM Phy 220 Chapter 4: Capacitors.
The two conductors a and b are insulated from each other, forming a capacitor. You increase the charge on a to +2Q and increase the charge on b to –2Q,
1 Capacitance and Capacitors Capacitance:  Any volume (material) that has net charge in it produces electric potential around it (Gauss’ Law).  The ratio.
Physics 212 Lecture 8, Slide 1 Physics 212 Lecture 8 Today's Concept: Capacitors How does a capacitor behave in a circuit? More circuit examples.
Physics 2102 Jonathan Dowling Physics 2102 Lecture 8 Capacitors II.
Physics 2113 Lecture: 16 WED 30 SEP Capacitance II Physics 2113 Jonathan Dowling.
12/4/2016 Advanced Physics Capacitance  Chapter 25 – Problems 1, 3, 8, (17), 19, (33), 39, 40 & 49.
Electrostatic Energy and Capacitance. Chapter Overview: b Electrostatic Potential Energy: 25-1 b Defining Capacitance: 25-2 b Electrostatic Energy and.
Chapter 19 Summary Bare-bones Style i.e. stuff you need down COLD.
Today’s agenda: Energy Storage in Capacitors. You must be able to calculate the energy stored in a capacitor, and apply the energy storage equations to.
Physics 102: Lecture 4, Slide 1 Capacitors (& batteries) Physics 102: Lecture 04.
Electrical Energy and Capacitance Capacitance. Capacitors and Charge Storage Capacitor – acts as a storehouse of charge and energy –Typically consists.
Consider a charged capacitor whose plates are separated by air (dielectric constant 1.00 ). The capacitor is electrically isolated from its surroundings.
What charge exists on a 30 μF capacitor (fully charged) with a 120 V potential difference between its plates and what is the energy stored? Ans: 3.6.
Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.

6. Capacitance and capacitors 6.1 Capacitors +Q -Q +Q -Q +Q 6.2 Capacitance [C]= 1 F = 1 C / V Definition:Units: Symbol: C is independent from: Q and ΔV.
Capacitor Device that can store electric charge Two conducting objects are placed near one another but not touching Power source charges up the plates,
Capacitors A capacitor is a device that has the ability “capacity” to store electric charge and energy.
Physics 102: Lecture 4, Slide 1 Capacitors! Physics 102: Lecture 04 Today’s lecture will cover Textbook Sections , , 6.
Example: a parallel plate capacitor has an area of 10 cm2 and plate separation 5 mm. 300 V is applied between its plates. If neoprene is inserted between.
Chapter 25 Capacitance In this chapter we will cover the following topics: -Capacitance C of a system of two isolated conductors.
Chapter 25 Capacitance In this chapter we will cover the following topics: -Capacitance C of a system of two isolated conductors.
6. Capacitance and capacitors
Capacitors, Batteries.
Energy Storage in Capacitors.
What charge exists on a 30 μF capacitor (fully charged) with a 120 V potential difference between its plates and what is the energy stored? Ans: 3.6.
Physics 014 Capacitance.
Chapter 25 Capacitance-II
Chapter 26 Examples 26.1 parallel-plate capacitor with air between the plates has an area A = 2.00 x m 2 and a plate separation d = 1.00 mm. Find.
Presentation transcript:

© 2012 Pearson Education, Inc. The two conductors a and b are insulated from each other, forming a capacitor. You increase the charge on a to +2Q and increase the charge on b to –2Q, while keeping the conductors in the same positions. As a result of this change, the capacitance C of the two conductors A.becomes 4 times great. B.B. becomes twice as great. C. remains the same. D. becomes 1/2 as great. E. becomes 1/4 as great. Q24.1

© 2012 Pearson Education, Inc. A24.1 The two conductors a and b are insulated from each other, forming a capacitor. You increase the charge on a to +2Q and increase the charge on b to –2Q, while keeping the conductors in the same positions. As a result of this change, the capacitance C of the two conductors A.becomes 4 times great. B.B. becomes twice as great. C. remains the same. D. becomes 1/2 as great. E. becomes 1/4 as great.

© 2012 Pearson Education, Inc. You reposition the two plates of a capacitor so that the capacitance doubles. There is vacuum between the plates. If the charges +Q and –Q on the two plates are kept constant in this process, what happens to the potential difference V ab between the two plates? A. V ab becomes 4 times as great. B. V ab becomes twice as great. C. V ab remains the same. D. V ab becomes 1/2 as great. E. V ab becomes 1/4 as great. Q24.2

© 2012 Pearson Education, Inc. A24.2 A. V ab becomes 4 times as great. B. V ab becomes twice as great. C. V ab remains the same. D. V ab becomes 1/2 as great. E. V ab becomes 1/4 as great. You reposition the two plates of a capacitor so that the capacitance doubles. There is vacuum between the plates. If the charges +Q and –Q on the two plates are kept constant in this process, what happens to the potential difference V ab between the two plates?

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. What is the equivalent capacitance of the two capacitors as a unit? A. C eq = 18  F B. C eq = 9  F C. C eq = 6  F D. C eq = 4  F E. C eq = 2  F Q24.3 a b 12  F 6  F

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. What is the equivalent capacitance of the two capacitors as a unit? A. C eq = 18  F B. C eq = 9  F C. C eq = 6  F D. C eq = 4  F E. C eq = 2  F A24.3 a b 12  F 6  F

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. If the charge on the 12-  F capacitor is 24 microcoulombs (24  C), what is the charge on the 6-  F capacitor? A. 48  C B. 36  C C. 24  C D. 12  C E. 6  C Q24.4 a b 12  F 6  F

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. If the charge on the 12-  F capacitor is 24 microcoulombs (24  C), what is the charge on the 6-  F capacitor? A. 48  C B. 36  C C. 24  C D. 12  C E. 6  C A24.4 a b 12  F 6  F

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. What is the equivalent capacitance of the two capacitors as a unit? A. C eq = 18  F B. C eq = 9  F C. C eq = 6  F D. C eq = 4  F E. C eq = 2  F Q24.5 a b 12  F6  F

© 2012 Pearson Education, Inc. A 12-  F capacitor and a 6-  F capacitor are connected together as shown. What is the equivalent capacitance of the two capacitors as a unit? A. C eq = 18  F B. C eq = 9  F C. C eq = 6  F D. C eq = 4  F E. C eq = 2  F A24.5 a b 12  F6  F

© 2012 Pearson Education, Inc. A. 48  C B. 36  C C. 24  C D. 12  C E. 6  C Q24.6 a b 12  F6  F A 12-  F capacitor and a 6-  F capacitor are connected together as shown. If the charge on the 12-  F capacitor is 24 microcoulombs (24  C), what is the charge on the 6-  F capacitor?

© 2012 Pearson Education, Inc. A. 48  C B. 36  C C. 24  C D. 12  C E. 6  C A24.6 a b 12  F6  F A 12-  F capacitor and a 6-  F capacitor are connected together as shown. If the charge on the 12-  F capacitor is 24 microcoulombs (24  C), what is the charge on the 6-  F capacitor?

© 2012 Pearson Education, Inc. Q24.7 A. becomes 4 times greater. B. becomes twice as great. C. remains the same. D. becomes 1/2 as great. E. becomes 1/4 as great. You reposition the two plates of a capacitor so that the capacitance doubles. There is vacuum between the plates. If the charges +Q and –Q on the two plates are kept constant in this process, the energy stored in the capacitor

© 2012 Pearson Education, Inc. You reposition the two plates of a capacitor so that the capacitance doubles. There is vacuum between the plates. If the charges +Q and –Q on the two plates are kept constant in this process, the energy stored in the capacitor A. becomes 4 times greater. B. becomes twice as great. C. remains the same. D. becomes 1/2 as great. E. becomes 1/4 as great. A24.7

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the charges on the plates remain constant. What effect does adding the dielectric have on the potential difference between the capacitor plates? A. The potential difference increases. B. The potential difference remains the same. C. The potential difference decreases. D. not enough information given to decide Q24.8

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the charges on the plates remain constant. What effect does adding the dielectric have on the potential difference between the capacitor plates? A. The potential difference increases. B. The potential difference remains the same. C. The potential difference decreases. D. not enough information given to decide A24.8

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the charges on the plates remain constant. What effect does adding the dielectric have on the energy stored in the capacitor? A. The stored energy increases. B. The stored energy remains the same. C. The stored energy decreases. D. not enough information given to decide Q24.9

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the charges on the plates remain constant. What effect does adding the dielectric have on the energy stored in the capacitor? A. The stored energy increases. B. The stored energy remains the same. C. The stored energy decreases. D. not enough information given to decide A24.9

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the potential difference between the plates remains constant. What effect does adding the dielectric have on the amount of charge on each of the capacitor plates? A. The amount of charge increases. B. The amount of charge remains the same. C. The amount of charge decreases. D. not enough information given to decide Q24.10

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the potential difference between the plates remains constant. What effect does adding the dielectric have on the amount of charge on each of the capacitor plates? A. The amount of charge increases. B. The amount of charge remains the same. C. The amount of charge decreases. D. not enough information given to decide A24.10

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the potential difference between the plates remains constant. What effect does adding the dielectric have on the energy stored in the capacitor? A. The stored energy increases. B. The stored energy remains the same. C. The stored energy decreases. D. not enough information given to decide Q24.11

© 2012 Pearson Education, Inc. You slide a slab of dielectric between the plates of a parallel-plate capacitor. As you do this, the potential difference between the plates remains constant. What effect does adding the dielectric have on the energy stored in the capacitor? A. The stored energy increases. B. The stored energy remains the same. C. The stored energy decreases. D. not enough information given to decide A24.11

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.