Inducing Current from Magnetic Field#
Use Lenz’s law to determine the direction of induced current in each case.
Part 1#
Scenario (a) depicts a conducting rod moving with velocity \(\overrightarrow{ v }\) along parallel connected wires, creating a closed loop. What direction is the induced current in the loop?
Answer Section#
Counterclockwise.
Clockwise.
No current is induced.
Part 2#
Scenario (b) depicts a circular ring of wire moving with velocity \(\overrightarrow{ v }\). The plane of the ring of wire is parallel to a magnetic field. What direction is the induced current in the ring?
Answer Section#
Counterclockwise.
Clockwise
No current is induced.
Part 3#
Scenario (c) depicts a circular ring of wire moving with velocity \(\overrightarrow{ v }\). The plane of the ring of wire is perpendicular to a magnetic field. What direction is the induced current in the ring?
Answer Section#
Counterclockwise.
Clockwise.
No current is induced.
Part 4#
Scenario (d) depicts a conducting rod moving with velocity \(\overrightarrow{ v }\) along parallel connected wires, creating a closed loop. What direction is the induced current in the loop?
Answer Section#
Counterclockwise.
Clockwise.
No current is induced.
Part 5#
Scenario (e) depicts a circular ring of wire perpendicular to an increasing magnetic field directed out of the screen. What direction is the induced current in the ring?
Answer Section#
Counterclockwise.
Clockwise.
No current is induced.
Part 6#
Scenario (f) depicts a circular ring of wire parallel to a decreasing magnetic field directed out of the screen. What direction is the induced current in the ring?
Answer Section#
Counterclockwise.
Clockwise.
No current is induced.
Attribution#
Problem is from the OpenStax University Physics Volume 2 textbook, licensed under the CC-BY 4.0 license.