AP Free Response Question
1999 B3
Printer Friendly Version
A rectangular conducting loop of width
w
, height
h
, and resistance
R
is mounted vertically on a non-conducting cart as shown above. The cart is placed on the inclined portion of a track and released from rest at position P
1
at a height
y
o
above the horizontal portion of the track. It rolls with negligible friction down the incline and through a uniform magnetic field
B
in the region above the horizontal portion of the track.
The conducting loop is in the plane of the page, and the magnetic field is directed into the page. The loop passes completely through the field with a negligible change in speed.
Express your answers in terms of the given quantities and fundamental constants.
(a) Determine the speed of the cart when it reaches the horizontal portion of the track.
(b) Determine the following for the time at which the cart is at position P
2
with one-third of the loop in the magnetic field.
i. The magnitude of the emf induced in the conducting loop
ii. The magnitude of the current induced in the conducting loop
(c) On the following diagram of the conducting loop, indicate the direction of the current when it is at position P
2.
(d) i. Using the axes below, sketch a graph of the magnitude of the magnetic flux Φ through the loop as a function of the horizontal distance x traveled by the cart, letting x = 0 be the position at which the front edge of the loop just enters the field. Label appropriate values on the vertical axis.
(d) ii. Using the axes below, sketch a graph of the current induced in the loop as a function of the horizontal distance x traveled by the cart, letting x = 0 be the position at which the front edge of the loop just enters the field. Let counterclockwise current be positive and label appropriate values on the vertical axis.
Topic Formulas
Description
Published Formula
capacitors in parallel
capacitors in series
elastic potential energy
electric current
Faraday's Law
Joule's Law
kinetic energy
magnetic field around a current-carrying wire
magnetic flux
magnetic force on a current-carrying wire
magnetic force on a moving charge
motional emf
Ohm's Law
potential energy
power
power
resistance in parallel
resistance in series
resistivity
work
Related Documents
Lab:
CP -
Series and Parallel Circuits
Labs -
A Battering Ram
Labs -
A Photoelectric Effect Analogy
Labs -
Air Track Collisions
Labs -
Ballistic Pendulum
Labs -
Ballistic Pendulum: Muzzle Velocity
Labs -
Bouncing Steel Spheres
Labs -
Collision Pendulum: Muzzle Velocity
Labs -
Conservation of Energy and Vertical Circles
Labs -
Conservation of Momentum in Two-Dimensions
Labs -
Forces Between Ceramic Magnets
Labs -
Inelastic Collision - Velocity of a Softball
Labs -
Loop-the-Loop
Labs -
Magnetic Field in a Solenoid
Labs -
Mass of an Electron
Labs -
Parallel and Series Circuits
Labs -
Ramps: Sliding vs Rolling
Labs -
RC Time Constants
Labs -
Resistance and Resistivity
Labs -
Resistance, Gauge, and Resistivity of Copper Wires
Labs -
Roller Coaster, Projectile Motion, and Energy
Labs -
Rotational Inertia
Labs -
Rube Goldberg Challenge
Labs -
Spring Carts
Labs -
Target Lab: Ball Bearing Rolling Down an Inclined Plane
Labs -
Telegraph Project
Labs -
Terminal Voltage of a Lantern Battery
Labs -
Video Lab: Blowdart Colliding with Cart
Labs -
Video LAB: Circular Motion
Labs -
Video Lab: M&M Collides with Pop Can
Labs -
Video Lab: Marble Collides with Ballistic Pendulum
Labs -
Wheatstone Bridge
Resource Lesson:
RL -
A Comparison of RC and RL Circuits
RL -
A Guide to Biot-Savart Law
RL -
A Special Case of Induction
RL -
Ampere's Law
RL -
An Introduction to DC Circuits
RL -
APC: Work Notation
RL -
Capacitors and Dielectrics
RL -
Conservation of Energy and Springs
RL -
Dielectrics: Beyond the Fundamentals
RL -
Eddy Currents plus a Lab Simulation
RL -
Electricity and Magnetism Background
RL -
Energy Conservation in Simple Pendulums
RL -
Famous Experiments: Cathode Rays
RL -
Filaments
RL -
Generators, Motors, Transformers
RL -
Gravitational Energy Wells
RL -
Induced Electric Fields
RL -
Induced EMF
RL -
Inductors
RL -
Introduction to Magnetism
RL -
Kirchhoff's Laws: Analyzing Circuits with Two or More Batteries
RL -
Kirchhoff's Laws: Analyzing DC Circuits with Capacitors
RL -
LC Circuit
RL -
Magnetic Field Along the Axis of a Current Loop
RL -
Magnetic Forces on Particles (Part II)
RL -
Magnetism: Current-Carrying Wires
RL -
Maxwell's Equations
RL -
Mechanical Energy
RL -
Meters: Current-Carrying Coils
RL -
Momentum and Energy
RL -
Motional EMF
RL -
Parallel Plate Capacitors
RL -
Potential Energy Functions
RL -
Principal of Least Action
RL -
RC Time Constants
RL -
RL Circuits
RL -
Rotational Dynamics: Pivoting Rods
RL -
Rotational Kinetic Energy
RL -
Springs and Blocks
RL -
Symmetries in Physics
RL -
Tension Cases: Four Special Situations
RL -
Torque on a Current-Carrying Loop
RL -
Work
RL -
Work and Energy
Review:
REV -
Drill: Induction
Worksheet:
APP -
Maggie
APP -
The Circuit Rider
APP -
The Cycle Shop
APP -
The Jogger
APP -
The Pepsi Challenge
APP -
The Pet Rock
APP -
The Pool Game
APP -
The Tree House
CP -
Conservation of Energy
CP -
DC Currents
CP -
Electric Power
CP -
Induction
CP -
Magnetism
CP -
Momentum and Energy
CP -
Momentum and Kinetic Energy
CP -
Ohm's Law
CP -
Parallel Circuits
CP -
Power Production
CP -
Power Transmission
CP -
RIVP Charts #1
CP -
RIVP Charts #2
CP -
Satellites: Circular and Elliptical
CP -
Series Circuits
CP -
Transformers
CP -
Work and Energy
NT -
Bar Magnets
NT -
Brightness
NT -
Cliffs
NT -
Elliptical Orbits
NT -
Escape Velocity
NT -
Gravitation #2
NT -
Induction Coils
NT -
Light and Heat
NT -
Magnetic Forces
NT -
Meters and Motors
NT -
Parallel Circuit
NT -
Ramps
NT -
Satellite Positions
NT -
Series Circuits
NT -
Shock!
WS -
Advanced Properties of Freely Falling Bodies #1
WS -
Advanced Properties of Freely Falling Bodies #2
WS -
Advanced Properties of Freely Falling Bodies #3
WS -
Capacitors - Connected/Disconnected Batteries
WS -
Charged Projectiles in Uniform Electric Fields
WS -
Combinations of Capacitors
WS -
Energy Methods: More Practice with Projectiles
WS -
Energy Methods: Projectiles
WS -
Energy/Work Vocabulary
WS -
Force vs Displacement Graphs
WS -
Induced emf
WS -
Introduction to R | I | V | P Charts
WS -
Introduction to Springs
WS -
Kinematics Along With Work/Energy
WS -
Kirchhoff's Laws: DC Circuits with Capacitors
WS -
Kirchhoff's Laws: Sample Circuit
WS -
Magnetic Forces on Current-Carrying Wires
WS -
Magnetic Forces on Moving Charges
WS -
Potential Energy Functions
WS -
Practice with Ampere's Law
WS -
Practice with Induced Currents (Changing Areas)
WS -
Practice with Induced Currents (Constant Area)
WS -
Practice: Momentum and Energy #1
WS -
Practice: Momentum and Energy #2
WS -
Practice: Vertical Circular Motion
WS -
Resistance, Wattage, and Brightness
WS -
Rotational Kinetic Energy
WS -
Static Springs: The Basics
WS -
Work and Energy Practice: An Assortment of Situations
WS -
Work and Energy Practice: Forces at Angles
TB -
34A: Electric Current
TB -
35A: Series and Parallel
TB -
36A: Magnets, Magnetic Fields, Particles
TB -
36B: Current Carrying Wires
TB -
Advanced Capacitors
TB -
Basic Capacitors
TB -
Basic DC Circuits
TB -
Exercises on Current Carrying Wires
TB -
Multiple-Battery Circuits
TB -
Textbook Set #6: Circuits with Multiple Batteries
TB -
Work, Power, Kinetic Energy
CB-ETS
Copyright © 1970-2023
All rights reserved.
Used with
permission
Mainland High School
Daytona Beach, FL 32114