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Transcript
Electricity & Magnetism Seb Oliver Lecture 14: Biot-Savart Law Summary: Lecture 13 • Practical uses of moving charge in magnetic field F qv B qE • Lorentz Force • Force on Wire FB I L B mv r qB Biot-Savart Law Introduction • We have discussed how an existing magnetic field influences moving charges (and thus currents) • We have not yet discussed the origin of magnetic fields • We will now see that currents (moving charges) produce magnetic fields • This can be thought of as the basic mechanism by which all magnetic fields are produced History • 1819 Hans Christian Oersted discovered that a compass needle was deflected by a current carrying wire • Then in 1920s Jean-Baptiste Biot and Felix Savart performed experiements to determine the force exerted on a compass by a current carrying wire • There results were as follows … Jean-Baptiste Biot & Felix Savart’s Results • dB the magnetic field produced by a small section of wire • ds a vector the length of the small section of wire in the direction of the current • r the positional vector from the section of wire to where the magnetic field is measured • I the current in the wire • angle between ds & r dB r ds • dB the magnetic field produced by a small section of wire • ds a vector the length of the small section of wire in the direction of the current • r the positional vector from the section of wire to where the magnetic field is measured • I the current in the wire • angle between ds & r • • • • • • dB r Biot & Savart’s Results ds dB perpendicular to ds dB perpendicular to r |dB| inversely proportional to |r|2 |dB| proportional to current I |dB| proportional to |ds| |dB| proportional to sin Biot – Savart Law • All these results could be summarised by one “Law” ds rˆ dB I r Putting in the constant 2 0 ds rˆ dB I 2 4 r Where 0 is the permeablity of free space Tm 0 4 10 A 7 Magnetic Field from Biot-Savart Law 0 ds rˆ dB I 2 4 r •We can use the Biot-Savart law to calculate the magnetic field due to any current carrying wire dB1 • B = dB1+dB2+…+dBi • I.e. B =SdB ds i rˆi 0 B I 2 4 ri r1 dB2 dB i r2 ri ds2 ds1 dsi One Example of using the BiotSavart Law Direction of the field around a long wire Magnetic Field from Biot-Savart Law • We can use the Biot-Savart law to see the direction of the field due to a wire segment dB1 r1 ds1 r ds dB1 r1 dB 0 ds rˆ dB I 2 4 r Another Right-Hand Rule Magnetic Field from Biot-Savart dB Law 1 r1 c.f. 0 ds rˆ dB I 2 4 r 1 Q | E | 40 | r |2 Of course there is no such thing as an isolated current segment! Summary • Biot-Savart Law – – – – 0 ds rˆ dB I 2 4 r 0 I (Field produced by wires) B 2R Centre of a wire loop radius R NI B 0 Centre of a tight Wire Coil with N turns 2R Distance a from long straight wire • Force between two wires • Definition of Ampere 0 I B 2a F 0 I1 I 2 l 2a
