Consider the configuration below. In order to generate the induced current, I, the magnet must be moving toward ...

A.
LEFT

B.
RIGHT

C.
It will depend on the speed of the magnet

D.
This is misleading as a moving magnet does not make generate a current

Transcribed Image Text:

**Electromagnetic Induction in a Closed Loop** The image illustrates the fundamental principles of electromagnetic induction using a simple setup. It features a bar magnet with its magnetic field lines interacting with a coil. 1. **Bar Magnet**: The magnet has two poles labeled as "S" (South) and "N" (North). The field lines are shown emanating from the North pole and entering the South pole, representing the direction of the magnetic field. 2. **Magnetic Field Lines**: These are depicted as blue arrows. The lines are more concentrated near the poles, indicating a stronger magnetic field in these areas. The arrows show the direction from the North to the South pole outside the magnet. 3. **Copper Coil**: Surrounding the magnet, there is an orange circular loop or coil. This represents a conductive coil through which an electric current can be induced. 4. **Current Flow (I)**: An arrow labeled "I" shows the direction of the induced current in the coil. The direction is given using the right-hand rule, suggesting that the current flows in a clockwise direction if viewed from the left side, facing the North pole of the magnet. The diagram exemplifies how moving a magnet through a coil or changing the magnetic field around the coil can induce an electric current, demonstrating Faraday's Law of Electromagnetic Induction. This principle is widely used in generating electricity in transformers, electric generators, and other devices. This visual representation aids in understanding the relationship between magnetic fields and induced electrical currents.