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Electromagnetic Induction Chapter 22 22.1 induced EMF and Induced Current If a coil of conducting material and a magnet are moving (relative to one another) an electric current can be induced. The changing magnetic field forces the electrons to move one direction or another. Since a source of emf is needed to produce a current, the coil itself behaves as if it were a source of emf; in this case an induced emf. How to induce emf Move a bar magnet near a coil Move a magnet away from a coil Move a coil toward a magnet Change the area of a coil in a constant magnetic field MUST have either magnet or coil moving MUST have a closed circuit or coil For I to exist 22.2 Motional EMF Moving a conducting rod through a constant magnetic field can separate the positive and negative charges existing within the rod. Once all possible charge movement has taken place, the separated charges cause an induced or motional emf. Emf exists as long as the rod moves Electric and magnetic forces balance at equilibrium Motional emf when v, B, and L are perpendicular BL • ε = 0 when v = 0m/s • ε is expressed in volts Motional EMF and Electrical Energy Magnetic force acts on charges in a conductor → motional emf → emf causes a current → second magnetic force is created Since emf cause a current that is perpendicular to B, a force that would slow down the rod is generated. A counterbalancing force must be applied to the rod by an external agent. Energy from Motional EMF The external force sill do work in such a system. Word done is equal to the electrical energy of the bulb. Remember: F = ILBsinθ can be used as a force in both F=ma and W= Fxcosθ. This concept follows the law of conservation of energy. 22.3 Magnetic Flux: Motional EMF and Magnetic Flux Magnetic Flux: product of magnetic field and area (BA) Symbolized by Greek letter phi Φ = BA magnitude of the induced emf is the change in flux divided by the time interval 𝜀= ∆Φ ∆𝑡 (-) appears in this equation b/c the direction of induced I is such that magnetic F acts on the rod to oppose its motion, therefore slowing down the rod A General Expression for φ Φ = 𝐵𝐴 𝑐𝑜𝑠φ If B or φ are not constant, the average value of the product Bcosφ is used to compute the flux. Magnetic flux is proportional to the number of field lines per unit area that pass through a surface perpendicular to the lines 22.4 Faraday’s Law All hail to Michael Faraday and Joseph Henry for discovering electromagnetic induction!!!! When there is a change in flux through a loop of wire, and emf is induced in the loop. ∆Φ 𝜀 = −𝑁 ∆𝑡 22.5 Lenz’s Law A method for determining the polarity of the induced emf is needed so that + and – terminals can be determined. Remember, two factors contribute to the net magnetic field penetrating a coil of wire ◦ Original magnetic field producing changing flux ◦ Induced current creating its own magnetic field (induced magnetic field) Lenz’s Law The induced emf resulting from a changing magnetic flux has a polarity that leads to an induced current whose direction is such that the induced magnetic field opposes the original flux change. Reasoning Strategy Determine whether the magnetic flux that penetrates a coil is increasing or decreasing. Find what the direction of the induced magnetic field must be so that it can oppose the change in flux by adding to or subtracting from the original field Once direction of induced magnetic field is found, use RHR-2 to determine the direction of the induced current. Then the polarity of the induced emf can be assigned because conventional current is directed out of the positive terminal, through the external circuit, and into the negative terminal. Last minute hints Electromagnetic induction is explained well here. The induced field is not always opposite to the external field, because Lenz’s law requires only that is must oppose the change in the flux that generates the emf. To oppose an increase in flux, the direction of the induced magnetic field must be opposite to the field of a bar magnet.