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Transcript
Lecture 12 : Electromagnetic induction β’ Faradayβs Law β’ Inductance β’ Energy stored in π΅-field Recap (1) β’ Maxwellβs Equations describe the electric field πΈ and magnetic field π΅ generated by stationary charge density π and current density π½: π π΅. π¬ = πΊπ π΅×π¬=π π΅. π© = π π΅ × π© = ππ π± Recap (2) β’ It requires work to assemble a distribution of electric charges against the electric forces β’ This work creates potential energy which we can think of as π stored in the electric field πΈ with density πΊπ π¬π π Time-varying fields β’ New and important phenomena and applications are produced when the electric or magnetic fields are not stationary, but time-varying Faradayβs Law β’ Faradayβs law says that an electric current is set up if the magnetic field through a circuit is changed Faradayβs Law β’ In mathematical terms, Faradayβs Law can be written in the form π½ = ππ± β ππ β’ π is the voltage (or electromotive force) created around the circuit β’ Ξ¦ is the magnetic flux through the circuit, given by Ξ¦ = π΅. ππ΄ β’ The minus sign indicates that the voltage causes a current to flow which opposes the change Faradayβs Law β’ An example is provided by a simple generator β’ Why does this work? β’ As the loop rotates, the area of the loop threaded by the magnetic field changes β’ This creates a voltage in the circuit, which powers the lamp Faradayβs Law β’ The fact that the induced voltage opposes the change that produced it is needed to satisfy conservation of energy Examples bringing a magnet towards and away from a coil of wire: Faradayβs Law β’ Faradayβs Law also applies if a wire is moving through a magnetic field Faradayβs Law β’ A voltage is induced between the ends of the wire which is equal to the rate of cutting of magnetic flux, π = πΞ¦ β ππ‘ β’ The free electrons in the wire feel a force πΉπ΅ = ππ£π΅ π£ β’ This force causes them to move along the wire as if there was an applied voltage π β’ The electrons separate until they set up an electric field πΈ which exerts a force πΉπΈ = ππΈ which cancels πΉπ΅ Faradayβs Law β’ A voltage is induced in the wire which is equal to the rate of cutting of magnetic flux, π = πΞ¦ β ππ‘ β’ If the wire has length πΏ, then the magnetic flux cut in time π‘ is contained in an area πΏπ£π‘. Hence, Ξ¦ = π΅. π΄ = π΅πΏπ£π‘ π£ πΏ β’ The voltage induced is hence π=β πΞ¦ ππ‘ = π΅πΏπ£ Faradayβs Law β’ Faradayβs Law π = β πΞ¦ ππ‘ requires a modification to Maxwellβs equation for electrostatics, π» × πΈ = 0 β’ Consider a closed loop πΏ bounding a surface π. The potential difference around the loop may be written as π = πΈ. π π = π» × πΈ . ππ΄, applying Stokeβs theorem β’ Since Ξ¦ = form π΅. π π΄, Faradayβs law can then be written in the π»×πΈ+ ππ΅ ππ‘ . ππ΄ = 0 β’ This holds true for any surface, hence π΅ × π¬ ππ© + ππ =π Faradayβs Law β’ What is the implication for potentials? ππ΅ + ππ‘ β’ The new relation π» × πΈ = 0 implies that we cannot derive the electric field as the gradient of an electrostatic potential, πΈ = βπ»π, for time-varying situations β’ However, by substituting in the magnetic vector potential π΅ = π» × π΄, we can derive πΈ = βπ»π β ππ΄ ππ‘ β’ This is a nice way to describe how electric fields are generated by both electrostatic charges (βπ»π) and changing magnetic fields (β ππ΄ ) ππ‘ Inductance β’ Current flowing in a circuit produces a magnetic field which threads the circuit itself! β’ By Faradayβs Law, this will cause an extra voltage to be induced in the circuit if the current is changed β’ This kind of circuit element is known as an inductor Inductance β’ If current πΌ flows in a circuit, inducing a magnetic field which threads flux Ξ¦ through the circuit, then the self-inductance πΏ of the circuit is defined by π± = π³ × π° β’ Consider a solenoid of length π, consisting of π turns of cross-sectional area π΄ β’ From previous lectures, the π ππΌ magnetic field is π΅ = π π β’ The magnetic flux is Ξ¦ = ππ΅π΄ (note: as it threads π loops) Inductance is measured in βHenrysβ (H) β honestly! β’ The self-inductance is hence π³= π± π° = π π π΅π π¨ π Inductance β’ Similarly, if current πΌ1 flows in one circuit, and produces a magnetic field which causes magnetic flux Ξ¦2 to thread a second circuit, then the mutual inductance π = Ξ¦2 /πΌ1 Inductance β’ Faradayβs Law is very useful for stepping a voltage up or down via an electrical transformer Why does this work? Energy stored in π΅-field β’ In electrostatics, we can think of the work done in assembling a configuration of charges as stored in the electric π field πΈ with energy density πΊπ π¬π π β’ Work is also done to set up a current in a circuit, to drive that πΞ¦ ππΌ current against the induced voltage π = β = βπΏ ππ‘ ππ‘ β’ The work done in a small time interval ππ‘ is given by ππ = β π ππ = βπ πΌ ππ‘ = πΏ πΌ ππΌ β’ Integrating this work between current πΌ = 0 and πΌ = πΌπππππ , we find that the total work is πΎ = π°πππππ π³π° π π π° = π π³π°πππππ π π Energy stored in π΅-field β’ We can think of this work being transformed to potential energy which is stored in the magnetic field β’ π0 ππΌ π0 π2 π΄ For a coil, substituting π΅ = and πΏ = π π 2 1 π΅ done π = πΏπΌ 2 , we find π = ×π΄π 2 2π0 into the work Volume of coil = π΄ π β’ We can think of storing energy in a π©-field with density π©π πππ Summary β’ A changing magnetic flux Ξ¦ through a πΞ¦ circuit induces a voltage π = β ππ‘ (Faradayβs Law), which opposes the change which produced it (Lenzβs Law) β’ The inductance πΏ of a circuit relates the flux to the current πΌ flowing : Ξ¦ = πΏ πΌ β’ Work is required to set up a current in a circuit; this can be considered stored in the magnetic field π΅ with density π΅2 2π0
