Physics 114 Exam 1 Spring 2013

Similar documents
Physics 114 Exam 1 Fall 2016

Physics 114 Exam 1 Fall 2015

CH 23. Gauss Law. A. Gauss law relates the electric fields at points on a (closed) Gaussian surface to the net charge enclosed by that surface.

University Physics (Prof. David Flory) Chapt_24 Sunday, February 03, 2008 Page 1

Phys 2102 Spring 2002 Exam 1

Chapter 23: Gauss Law. PHY2049: Chapter 23 1

Chapter 22 Gauss s Law. Copyright 2009 Pearson Education, Inc.

Sample Question: A point in empty space is near 3 charges as shown. The distances from the point to each charge are identical.

How to define the direction of A??

Chapter (2) Gauss s Law

Chapter 22 Gauss s Law

Gauss s Law. Phys102 Lecture 4. Key Points. Electric Flux Gauss s Law Applications of Gauss s Law. References. SFU Ed: 22-1,2,3. 6 th Ed: 16-10,+.

Flux. Flux = = va. This is the same as asking What is the flux of water through the rectangle? The answer depends on:

Electric Flux. If we know the electric field on a Gaussian surface, we can find the net charge enclosed by the surface.

Chapter 23. Gauss Law. Copyright 2014 John Wiley & Sons, Inc. All rights reserved.

Chapter 22 Gauss s Law. Copyright 2009 Pearson Education, Inc.

Physics 208, Spring 2015 Exam #1

3. A solid conducting sphere has net charge of +6nC. At electrostatic equilibrium the electric field inside the sphere is:

Chapter 21: Gauss s Law

AP Physics C - E & M

Ampere s Law. Outline. Objectives. BEE-Lecture Notes Anurag Srivastava 1

1. (a) +EA; (b) EA; (c) 0; (d) 0 2. (a) 2; (b) 3; (c) 1 3. (a) equal; (b) equal; (c) equal e; (b) 150e 5. 3 and 4 tie, then 2, 1

Chapter 21 Chapter 23 Gauss Law. Copyright 2014 John Wiley & Sons, Inc. All rights reserved.

Chapter 23. Gauss s Law

3/22/2016. Chapter 27 Gauss s Law. Chapter 27 Preview. Chapter 27 Preview. Chapter Goal: To understand and apply Gauss s law. Slide 27-2.

Exam 1 Solution. Solution: Make a table showing the components of each of the forces and then add the components. F on 4 by 3 k(1µc)(2µc)/(4cm) 2 0

Chapter 24. Gauss s Law

Cutnell/Johnson Physics

Quick Questions. 1. Two charges of +1 µc each are separated by 1 cm. What is the force between them?

PH 222-2C Fall Gauss Law. Lectures 3-4. Chapter 23 (Halliday/Resnick/Walker, Fundamentals of Physics 8 th edition)

Chapter 2 Gauss Law 1

Chapter 24. Gauss s Law

Physics 202: Spring 1999 Solution to Homework Assignment #3

PHYSICS - CLUTCH CH 22: ELECTRIC FORCE & FIELD; GAUSS' LAW

Profs. D. Acosta, A. Rinzler, S. Hershfield. Exam 1 Solutions

E. not enough information given to decide

Physics 2212 K Quiz #1 Solutions Summer q in = ρv = ρah = ρa 4

Physics 2049 Exam 1 Solutions Fall 2002

Physics 9 WS E3 (rev. 1.0) Page 1

Chapter 24. Gauss s Law

Worksheet for Exploration 24.1: Flux and Gauss's Law

Exam 1 Multiple Choice Practice Problems Physics 1251 TA: Clark/Sullivan

Chapter 22. Dr. Armen Kocharian. Gauss s Law Lecture 4

Phys102 General Physics II. Chapter 24: Gauss s Law

HOMEWORK 1 SOLUTIONS

Exam 1 Solutions. Note that there are several variations of some problems, indicated by choices in parentheses. Problem 1

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

week 3 chapter 28 - Gauss s Law

Fall 12 PHY 122 Homework Solutions #2

PHYS102 - Gauss s Law.

PHYSICS. Chapter 24 Lecture FOR SCIENTISTS AND ENGINEERS A STRATEGIC APPROACH 4/E RANDALL D. KNIGHT

Homework 4 PHYS 212 Dr. Amir

Essential University Physics

Physics (2): Problem set 1 solutions

Electric Field Lines. lecture 4.1.1

LECTURE 15 CONDUCTORS, ELECTRIC FLUX & GAUSS S LAW. Instructor: Kazumi Tolich

Physics 202 Midterm Exam 1 Oct 2 nd, 2012

1. ELECTRIC CHARGES AND FIELDS

Gauss s Law. Chapter 22. Electric Flux Gauss s Law: Definition. Applications of Gauss s Law

Gauss s Law. Name. I. The Law: , where ɛ 0 = C 2 (N?m 2

Physics Lecture: 09

CPS lesson Electric Field ANSWER KEY

PHY102 Electricity Topic 3 (Lectures 4 & 5) Gauss s Law

Gauss s Law & Potential

Chapter 23 Term083 Term082

Lecture 4-1 Physics 219 Question 1 Aug Where (if any) is the net electric field due to the following two charges equal to zero?

The Basic Definition of Flux

Chapter 24. Gauss s Law

Phys222 S11 Quiz 2: Chapters Name: = 80 nc, and q = 24 nc in the figure, what is the magnitude of the total electric force on q?

Practice Questions Exam 1/page1. PES Physics 2 Practice Exam 1 Questions. Name: Score: /.

Electricity & Magnetism Lecture 4: Gauss Law

More Gauss, Less Potential

Electric Flux. To investigate this, we have to understand electric flux.

ELECTRIC FORCES AND ELECTRIC FIELDS

Electric Field and Gauss s law. January 17, 2014 Physics for Scientists & Engineers 2, Chapter 22 1

Physics Lecture 13

Physics II Fiz Summer 2017

Read this cover page completely before you start.

VU Mobile Powered by S NO Group All Rights Reserved S NO Group 2012

Chapter 28. Gauss s Law

IMPORTANT: LABS START NEXT WEEK

Experiment III Electric Flux

PHYSICS 241 TEST 1 Monday, February 17, 2003

Electric Flux and Gauss Law

Junior-level Electrostatics Content Review

Lecture 14. PHYC 161 Fall 2016

3 Chapter. Gauss s Law

PHYS 1441 Section 002 Lecture #6

PHYS1212 Exam#2 Spring 2014

PHYSICS 122D, Winter 2009, Version A Exam 2, PAGE 1

ELECTRIC FORCES AND ELECTRIC FIELDS

Questions Chapter 23 Gauss' Law

Chapter 21: Gauss law Tuesday September 13 th. Gauss law and conductors Electrostatic potential energy (more likely on Thu.)

PHYS 2212 (Modern) Review. Electric Force and Fields

Where, ε 0 = Permittivity of free space and = Nm 2 C 2 Therefore, force

1. A ring of radius α has a charge distribution on it that varies as λ(θ) = λ 0 sin(θ), where λ 0 > 0, as shown in the figure.

Gauss Law 1. Name Date Partners GAUSS' LAW. Work together as a group on all questions.

24 Gauss s Law. Gauss s Law 87:

Electric Flux and Gauss s Law

Physics 212 Exam I Sample Question Bank 2008 Multiple Choice: choose the best answer "none of the above" may can be a valid answer

Transcription:

Physics 114 Exam 1 Spring 2013 Name: For grading purposes (do not write here): Question 1. 1. 2. 2. 3. 3. Problem Answer each of the following questions and each of the problems. Points for each question and problem are indicated in red with the amount being spread equally among parts (a,b,c etc). Be sure to show all your work. Use the back of the pages if necessary.

Question 1. (10 points) A negatively charged rod is brought close to a small metal ball suspended by a thin thread, but doesn t touch it. (a) What does the sphere do, if anything. (b) What do the charges in sphere do? Now, still without the rod touching the sphere, but while holding the rod close to the sphere, you ground the sphere by touching it. (c) What do charges in the sphere or elsewhere (like from the ground) do at this point. You take away your hand (the connection to ground). (d) What is the net charge of the sphere now (positive, negative, or neutral)? (a) The sphere is attracted to the rod and moves towards it (b) They polarize; the negative charges move away from the rod so that the left side is positive and right side is negative. (c) Negative charges in the sphere flow into the ground. (d) The charge on the sphere is positive.

Question 2. (10 points) Consider point A in the figure below located an arbitrary distance from two positive point charges in otherwise empty space. (a) Is it possible for an electric field to exist at point A in empty space? (b) Does charge exist at this point? (c) Does a force exist at this point? (a) Yes. Electric field permeate space. (b) No. It is empty space. (c) No. There is no charge there. There is no force.

Question 3. (10 points). Consider the following image. (Take q 1 = 3.00 nc and q 2 = - 8.00nC.) (a) Find the net electric flux through the cube shown in the figure above. (b) Can you use Gauss's law to find the electric field on the surface of this cube? Explain why or why not. (a) The flux is just the charge inside divided by 0. This is 3 10-9 C / 8.85 10-9 C 2 /N-m 2 = 339 N-m 2 /C (b) No. Gauss s law only can be applied in cases of a symmetric charge distribution. In addition, the symmetry of the Gaussian surface should match the field in the sense that you will want the field to be constant over the surface. Here, the field due to q 1 is not constant over the surfaces. In addition, the field due to q 2 also contributes to the field on the surface. If you knew the positions of the charges relative to the cube, you could calculate the field at the surface by integration, but you could not use Gauss law due to a lack of symmetry.

Problem 1. (15 points) Three point charges with magnitude given by q = 2 C lie along a circle of radius r= 3 m at angles of 30, 150, and 270 as shown in the figure below. (a) Find the vector resultant electric field at the center of the circle. (b) If a point charge Q = 10 nc is placed at the origin, what would the magnitude of the net force be on that charge be due to the three charges shown in the Figure. (a) This is solved by adding the vector electric fields due to all three charges. It is apparent that the x-component of the field due to the two positive charges cancel each other out and the negative charge creates no electric in the x-direction. Thus, there is only a y- direction of the resultant field. Note that the y-component of the field due to each charge is in the negative direction (downward, imagine a positive test charge at the origin). To do this properly, it could be useful to draw the E field vectors y x Note that the electric field vectors from the positive charges point in directions minus 30 degrees below the positive and negative x-axis. That is the angles are 210 and 330 degrees.

k e E= 2 4sin(270) 2sin(210) + 2 sin(330) j N r C 9 910 = 2 4 1-1) j N 3 C 9 610 j N C (b) To get the force on the charge we just apply E F q. Here q = 10 nc = 1 0 10-8 C. 9 8 Thus, F=( 610 )(110 ) j N = -60 j N

Problem2. (15 points) The figure below represents the top view of a cubic gaussian surface in a uniform electric field = 1 N/C oriented parallel to the top and bottom faces of the cube. The field makes an angle θ with side, and the area of each face is A = 2 m 2. (a) If = 0 o (so the field would go straight up in the picture), what would be the flux through side 1? (b) If = 0 o, what would be the flux through side 2? (c) If = 30 o what would be the flux through side 1? (d) If = 30 o what would be the flux through side 2? (e) What is the total flux through the cube (summing over all sides) in both cases ( = 0 o and = 30 o ). Note there are no charges inside the surface. (a) The Flux is given by E. da E. A, where the integral disappears since this is a constant electric field and we have flat surfaces. The vector A points upward in the diagram. Thus we have that the flux is just given by = EA cos() = 1 N/C 2 m 2 cos(0) = 2 N-m 2 /C (b) The vector A points to the right in figure. Thus, = EA cos() = 1 N/C 2 m 2 cos(90) = 0 (c) = EA cos() = 1 N/C 2 m 2 cos(30) = 1.73 N-m 2 /C (d) = EA cos() = 1 N/C 2 m 2 cos(120) = - 1 N-m 2 /C (e) The total flux is zero in both cases Gauss law says that the total flux will be zero if there are no charges inside and there are none.

Problem 3. (15 points) A point charge q = 5 mc is placed at the center of a spherical conducting shell of inner radius r 1 = 1 m and r 2 = 2. M that has no net charge on it. Calculate the electric field (a) at r = 0.5 m (b) at r = 1.5 m (c) r = 3 m (d) What is the total charge that is distributed on the inner surface of the spherical shell? (e) What is the total charge that is distributed on the outer surface of the spherical shell [Note that the total net charge on the spherical shell is zero]. r 2 q r 1 (a) Gauss s law states that EdA. qenc / 0. The charge inside here is just q = 5 mc. The field will be radial outward. Thus we have E 4r 2 = q/ 0 E 4 2 = (5 10-3 )/(8.85 10-12 ) E = 1.80 10 8 N/C (b) Here E = 0 since we are inside the conductor. (c) This is like part (a) except r is different. E 4r 2 = q/ 0 E 4 2 = (5 10-3 )/(8.85 10-12 ) E = 5.00 10 6 N/C (d) Draw a Gaussian surface inside the sphere (in the metal). The flux through that surface is zero as E is zero. Thus, the total charge is zero. Since the point charge is q = 5 mc, the charge on the inner surface must be 5 mc. (e) Since the total, net charge on the conducting shell is 0, there must be + 5 mc on the outer surface.

Possibly Useful Information F 1 4 0 q q 1 2 2 r e = 1.6 X 10-19 C E k e q 2 4 0r 1 910 N m /C 4 0 9 2 2 2 2 0 885. X 10-12 ( C / Nm ) E F q 0 0 0 EdA. r = xi + yj + zk q enc

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