Phys 102 Spg Exam No. 2 Solutions

Similar documents

Phys222 Winter 2012 Quiz 4 Chapters Name

Review Questions PHYS 2426 Exam 2

Physics 121 Sample Common Exam 3 NOTE: ANSWERS ARE ON PAGE 6. Instructions: 1. In the formula F = qvxb:

104 Practice Exam 2-3/21/02

AP2 Magnetism. (c) Explain why the magnetic field does no work on the particle as it moves in its circular path.

Sample Questions for the AP Physics 1 Exam

Magnetism. d. gives the direction of the force on a charge moving in a magnetic field. b. results in negative charges moving. clockwise.

Candidate Number. General Certificate of Education Advanced Level Examination June 2014

1. Units of a magnetic field might be: A. C m/s B. C s/m C. C/kg D. kg/c s E. N/C m ans: D

F B = ilbsin(f), L x B because we take current i to be a positive quantity. The force FB. L and. B as shown in the Figure below.

Force on Moving Charges in a Magnetic Field

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

1. The diagram below represents magnetic lines of force within a region of space.

Physics 9e/Cutnell. correlated to the. College Board AP Physics 1 Course Objectives

Candidate Number. General Certificate of Education Advanced Level Examination June 2010

Physics 112 Homework 5 (solutions) (2004 Fall) Solutions to Homework Questions 5

Conceptual: 1, 3, 5, 6, 8, 16, 18, 19. Problems: 4, 6, 8, 11, 16, 20, 23, 27, 34, 41, 45, 56, 60, 65. Conceptual Questions

The purposes of this experiment are to test Faraday's Law qualitatively and to test Lenz's Law.

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics Spring 2013 Conflict Exam Two Solutions

Physics 221 Experiment 5: Magnetic Fields

AP Physics Electricity and Magnetism #4 Electrical Circuits, Kirchoff s Rules

PHYS 222 Spring 2012 Final Exam. Closed books, notes, etc. No electronic device except a calculator.

Magnetic Fields. I. Magnetic Field and Magnetic Field Lines

CLASS TEST GRADE 11. PHYSICAL SCIENCES: PHYSICS Test 3: Electricity and magnetism

Direction of Induced Current

Torque and Rotational Equilibrium

Induced voltages and Inductance Faraday s Law

Physics 25 Exam 3 November 3, 2009

Experiment #5, Series and Parallel Circuits, Kirchhoff s Laws

3600 s 1 h. 24 h 1 day. 1 day

( )( 10!12 ( 0.01) 2 2 = 624 ( ) Exam 1 Solutions. Phy 2049 Fall 2011

UNIVERSITY OF SASKATCHEWAN Department of Physics and Engineering Physics

Candidate Number. General Certificate of Education Advanced Level Examination June 2012

Q27.1 When a charged particle moves near a bar magnet, the magnetic force on the particle at a certain point depends

Copyright 2011 Casa Software Ltd. Centre of Mass

General Physics (PHY 2140)

Physics 1A Lecture 10C

Chapter 22 Magnetism

E/M Experiment: Electrons in a Magnetic Field.

Modern Physics Laboratory e/m with Teltron Deflection Tube

TEACHER S CLUB EXAMS GRADE 11. PHYSICAL SCIENCES: PHYSICS Paper 1

VELOCITY, ACCELERATION, FORCE

E X P E R I M E N T 8

PHYS 211 FINAL FALL 2004 Form A

Lab 4: Magnetic Force on Electrons

Physics 6C, Summer 2006 Homework 2 Solutions

Solution Derivations for Capa #11

Practice final for Basic Physics spring 2005 answers on the last page Name: Date:

Pre-lab Quiz/PHYS 224 Magnetic Force and Current Balance. Your name Lab section

Chapter 11 Equilibrium

FORCE ON A CURRENT IN A MAGNETIC FIELD

TORQUE AND FIRST-CLASS LEVERS

Slide 1 / 26. Inductance by Bryan Pflueger

Chapter 19 Magnetic Forces and Fields

Measurement of Charge-to-Mass (e/m) Ratio for the Electron

Solution Derivations for Capa #11

Unit 4 Practice Test: Rotational Motion

Chapter 27 Magnetic Field and Magnetic Forces

Displacement (x) Velocity (v) Acceleration (a) x = f(t) differentiate v = dx Acceleration Velocity (v) Displacement x

45. The peak value of an alternating current in a 1500-W device is 5.4 A. What is the rms voltage across?

Electromagnetism Laws and Equations

PHY121 #8 Midterm I

= (0.400 A) (4.80 V) = 1.92 W = (0.400 A) (7.20 V) = 2.88 W

Physics 41, Winter 1998 Lab 1 - The Current Balance. Theory

When the fluid velocity is zero, called the hydrostatic condition, the pressure variation is due only to the weight of the fluid.

EE301 Lesson 14 Reading: , , and

The DC Motor. Physics 1051 Laboratory #5 The DC Motor

Solving Simultaneous Equations and Matrices

ELECTRIC FIELD LINES AND EQUIPOTENTIAL SURFACES

Exercises on Voltage, Capacitance and Circuits. A d = ( ) π(0.05)2 = F

ElectroMagnetic Induction. AP Physics B

Physics 30 Worksheet #10 : Magnetism From Electricity

Mechanics lecture 7 Moment of a force, torque, equilibrium of a body

Chapter 4. Forces and Newton s Laws of Motion. continued

PS-6.2 Explain the factors that determine potential and kinetic energy and the transformation of one to the other.

Lab #4 - Linear Impulse and Momentum

physics 112N magnetic fields and forces

C B A T 3 T 2 T What is the magnitude of the force T 1? A) 37.5 N B) 75.0 N C) 113 N D) 157 N E) 192 N

Lab 7: Rotational Motion

Linear Motion vs. Rotational Motion

Physics 2A, Sec B00: Mechanics -- Winter 2011 Instructor: B. Grinstein Final Exam

Circuits. The light bulbs in the circuits below are identical. Which configuration produces more light? (a) circuit I (b) circuit II (c) both the same

How To Understand The Physics Of A Charge Charge

Magnetic Field and Magnetic Forces

Reading assignment: All students should read the Appendix about using oscilloscopes.

AP1 Electricity. 1. A student wearing shoes stands on a tile floor. The students shoes do not fall into the tile floor due to

CURRENT ELECTRICITY - I

Magnetic Fields and Their Effects

Problem Solving 8: RC and LR Circuits

PHYSICS 111 HOMEWORK SOLUTION #9. April 5, 2013

F N A) 330 N 0.31 B) 310 N 0.33 C) 250 N 0.27 D) 290 N 0.30 E) 370 N 0.26

AP Physics - Chapter 8 Practice Test

Chapter 22: Electric motors and electromagnetic induction

Homework # Physics 2 for Students of Mechanical Engineering

Objectives. Capacitors 262 CHAPTER 5 ENERGY

CHAPTER 28 ELECTRIC CIRCUITS

Physics 2B. Lecture 29B

Objective: Equilibrium Applications of Newton s Laws of Motion I

Rotation: Moment of Inertia and Torque

Transcription:

Phys 102 Spg. 2008 Exam No. 2 Solutions I. (20 pts) A 10-turn wire loop measuring 8.0 cm by 16.0 cm carrying a current of 2.0 A lies in the horizontal plane and is free to rotate about a horizontal axis through its center as shown below. A 50-g mass hangs from one side of the loop. A uniform horizontal magnetic field is also present, as shown. What magnetic field strength is required to hold the loop in its horizontal position? (take g to be 9.8 m s -1 ). Answer: The loop will remain in its horizontal position when the sum of the torque generated by the mass and the torque from the loop s magnetic moment interaction with the magnetic field is zero. Th e loop s magnetic moment is a vector directed out of the page and is given by, where I is the current, N is the number of turns in the loop, A is the area enclosed by the loop and B is the magnitude of the B field. Absent a counteracting torque, will cause the loop to rotate counterclockwise with respect to the horizontal axis of rotation. The torque generated by the mass is, where is the lever arm the perpendicular distance from the force to the axis of rotation and is the force applied by the mass. will cause the loop to rotate clockwise with respect to the horizon tal axis of rotation. Setting these torques equal yields 0.05 9.8 0.04 2 10 0.08 0.16. 1

II. (25 pts) In the circuit shown below, the reading of the ammeter (which has negligible resistance) is the same with both switches open and both closed. Find the resistance R. Answer: With the switches both open, the circuit can be redrawn as shown The current through the ammeter can now be determined using, where 100Ω 300Ω 50Ω 450Ω., which g ives... Ω With the switches closed, the circuit can be drawn as shown R can then be determined using Kirchhoff s Rules (with the currents shown to the right and using the value obtained for what is now I 2, obtained in the first part of this problem). 3.33 10 0 1.5 300 0 100 3.33 1 0 R 0 R can be derived from these equations in a number of different ways. One way is to note that the third equation directly gives the value for RI 3 which can then be plugged into the second equation to find I 1, which can then be used to find I 3 by the first equation, and finally that result plugged into the value for RI 3 to obtain R. So, RI 3 equals 0.333V, which means... 3.89 10. Therefore, 3.89 10 3.33 10 0.56 10 and so 0.333 0.56 10. Ω 2

III. (25 pts) Consider the circuit shown below, where switches S 1 and S 2 are open and C 1, C 2 and C 3 are uncharged. (a) If S 1 is now closed how much charge flows through it as C 1 and C 2 charge up? Answer: The circuit with just S 1 closed is as shown to the right (with S 2 open, no current can flow and therefore C 3 can be ignored.) The amount of charge Q that will flow through S 1 will be sufficient to satisfy the loop rule that the voltage of the emf source will be divided among the potential drops across the 2 capacitors according to the equation 0 9 6 10 12 10 6 10 12 10. (b) What is now the potential at point A? (Take the potential on the negative terminal of the source of emf to be 0V). Answer: The potential at point A with respect to the negative terminal of the source of the emf is simply the potential across C 2, which is V Q C.. When C 1 and C 2 are fully charged, S 2 is closed. The answers to the last 3 parts can be determined by analyzing the circuit shown at right, after it reaches steady state. Part (c) is asking for the amount of charge, Q 3, which will accumulate on C 3. Since Q 3 = C 3 V 3, the voltage across C 3 must be determined, which is the answer to part (d). This can be solved for by first determining the equivalent capacitance,, for C 2 and C 3, then determining the amount of 3

charge, which will accumulate on the 2 capacitors, C 1 and, and then determining the potentials across those capacitors, similar to the approach used in parts (a) and (b). Part (e) then asks for the difference between the amount of charge that accumulated on C 1 before and after switch S 2 is closed, or the difference between Q determined in part (a) and Q 1 determined here. (c) How much charge flows through S 2? Answer: Using the approach outlined above, 36. 9 6 10 36 10 6 10 12 10 4.63 10 4.63 10 1.29 36 The amount of charge flowing through S 2, therefore, will be 24 10 1.29. (d) What is the final potential at point A? Answer: The final potential at poin t A will be. (e) How much additional charge passed through S 1 after closing S2 and in what direction did it flow? Answer: 4.63 10 3.6 10.. Since the final charge on C 1 is greater tha n the initial charge, the charge flow is to the right. 4

Last Name: First Name: Physics 102 Spring 2008: Exam #2 Multiple-Choice Questions 1. Consider the arrangement of resistors shown below. The equivalent resistance between A and B is (a) ¼ Ω (b) ½ Ω (c) 1 Ω (d) 2 Ω (e) 4 Ω 2. Consider parallel plate capacitors of identical capacitance C that are connected in parallel as sho wn. They are initially charged such that they store a total energy U and are then isolated. A dielectric of dielectric strength κ is now inserted to entirely fill the gap between the plates of one capacitor. The energy shared by the pair of capacitors is (a) Unchanged (b) 2 / 1 κ (c) 1 κ /2 (d) 4 / 1 κ 5

(e) 1 κ /4 3. A capacitor is charged to 12 V and then connected between points A and B in the figure below, with the positive plate connected to point A. What is the current through the 2 kω resistor a long time after the capacitor is connected? (a) 0 ma (b) 2 ma (c) 4 ma (d) 6 ma (e) 8 ma 4. Five identical bulbs are connected as shown to a source of emf ε. Which bulb is brightest? (a) A (b) B (c) C (d) D (e) E 6

F or the next two questions, consider the circuit shown below where C 1 and C 2 are initially uncharged and switch S is open. 5. The current through the source of emf immediately after S is closed is ( a) ε/r 1 (b) ε/r 2 (c) ε/(r + R ) 1 2 (d) ε/(r 1 + R 3 ) (e) ε/r2c 1 6. Following closure of the switch, the current through R 3 (a) immediately jumps up before decreasing to zero. (b) immediately jumps up before decreasing to a steady equilibrium value. (c) builds up to a steady, non-zero equilibrium value. ( d) initially builds up but then decreases to zero. (e) remains zero. 7

7. A static magnetic field CANNOT do which of the following? (a) exert a force on a charged particle (b) accelerate a charged particle (c) change the momentum of a charged particle (d) change the kinetic energy of a charged particle (e) reverse the direction of motion of a charged particle. 8. When a cathode-ray tube (television picture-tube) with a horizontal axis is placed in a magnetic field directed vertically up, the electrons emitted from the cathode follow one of the paths shown and strike the screen at one of the numbered points. The spot that most nearly represents the correct path is (a) 1 (b) 2 (c) 3 (d) 4 (e) 5 8

9. Three current loops are depicted below, along with their dimensions and current direction. If a uniform magnetic field is pointing to the right of the page, which current loop has the greatest magnetic potential energy compared to its minimal value of magnetic potential energy? ( a) The rectangular current loop. (b) The triangular current loop. (c) The circular current loop. (d) They all have the same magnetic potential energy relative to their minimal magnetic potential energy. (e) More information is required. 10. An initially uncharged metal bar is moved at constant velocity to the right through a region where there is a uniform magnetic field pointing into the page. Which of the above diagrams best describes the charge distribution on the surface of the metal bar? (a) a (b) b (c) c 9

(d) d (e) e 10

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information