A flat circular coil with 105 turns, a radius of 4.00 x 10^-2 m, and a resistance of .480 Ω is exposed to an external magnetic field that is directed perpendicular to the plane of the coil. The magnitude of the external magnetic field is changing at a rate of ΔB/Δt = .783 T/s, thereby inducing a current in the coil. Find the magnitude of the magnetic field at the center of the coil that is produced by the induced current.

A flat circular coil with 106 turns, a radius of 2.43x10^-2 m, and a resistance of 0.328 Ω is exposed toanexternal magnetic field that is directed perpendicular to theplaneof the coil. The magnitude of the external magnetic fieldischanging at a rate of ΔB/Δt = 0.772T/s, therebyinducing a current in the coil. Find the magnitude ofthe magneticfield at the center of the coil that is produced bythe inducedcurrent.

A flat circular coil with 106 turns, a radius of 2.43x10^-2 m, and a resistance of 0.328 Ω is exposed toanexternal magnetic field that is directed perpendicular to theplaneof the coil. The magnitude of the external magnetic fieldischanging at a rate of ΔB/Δt = 0.772T/s, therebyinducing a current in the coil. Find the magnitude ofthe magneticfield at the center of the coil that is produced bythe inducedcurrent.

A flat circular coil with 106 turns, a radius of 2.43x10^-2 m, and a resistance of 0.328 Ω is exposed toanexternal magnetic field that is directed perpendicular to theplaneof the coil. The magnitude of the external magnetic fieldischanging at a rate of ΔB/Δt = 0.772T/s, therebyinducing a current in the coil. Find the magnitude ofthe magneticfield at the center of the coil that is produced bythe inducedcurrent.