The Direction of Magnetic Field in a Cylindrical Capacitor with Exponentially Decreasing Current

What is the direction of the magnetic field between the two cylinders while the capacitor is charging?

The magnetic field in a cylindrical capacitor with current flowing from the positive inner cylinder to the negative outer one would be in the counterclockwise direction. This is consistent with the right-hand rule, Ampere's Law, and Faraday's Law. The direction of the field also corresponds to a decreasing exponential current.

Understanding the Direction of Magnetic Field in a Cylindrical Capacitor

Magnetic Field Direction: The direction of the magnetic field in a cylindrical capacitor can be determined using the right-hand rule that is associated with Ampere's Law. In this particular scenario, since the current is flowing from the positive inner cylinder to the negative outer one, you would point your thumb in the direction of the current and curl your fingers. Your fingers will denote the direction of the magnetic field, which in this case would be in the counterclockwise direction. Consistency with Laws: The counterclockwise direction of the magnetic field between the two cylinders is consistent with both Ampere's Law and Faraday's Law. Ampere's Law states that the magnetic field around a current-carrying conductor takes a specific direction based on the direction of the current flow, while Faraday's Law explains how a changing magnetic field induces an electromotive force. Exponential Current: The direction of the magnetic field also corresponds to a decreasing exponential current. As the current decreases over time, the magnetic field induced between the cylinders follows suit and maintains a counterclockwise direction. Therefore, the direction of the magnetic field between the two cylinders of a cylindrical capacitor while it is charging with an exponentially decreasing current is counterclockwise, in line with the principles of Ampere's Law, Faraday's Law, and the behavior of a decreasing exponential current.
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