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Magnetic fields & electromagnetic induction Learning outcomes describe magnetic fields in terms of magnetic flux & flux density use Fleming’s left and right hand rules to describe interactions between magnetic field & current quantitatively describe B fields around a straight current-carrying wire and a solenoid quantitatively describe the force on a charged particle moving at right angles to a uniform B field explain electromagnetic induction using Faraday’s & Lenz’s law use the concept of flux linkage to explain how transformers work describe how B fields are used in circular particle accelerators recall the postulates and key consequences of special relativity solve related quantitative problems Teaching challenges • fields are abstract • involves 3-D thinking but generally illustrated in 2-D • involves rates of change • different concepts have similar names • some physical quantities have a variety of equivalent units • students may need simple trigonometry to find the magnetic flux, or magnetic force, correctly identifying angle . Permanent magnets Magnetic field lines start and finish at poles. Physicists picture this as a ‘flow’ in magnetic circuit. • magnetic flux (phi), unit Weber • magnetic flux density B, unit Weber m-2 or Tesla B A BAcos Carl Gauss & Wilhelm Weber investigated geomagnetism in 1830s, made accurate measurements of magnetic declination and inclination, built the first electromagnetic telegraph. Defining magnetic flux density Fleming’s left-hand rule: Force on the wire is perpendicular to both l and B. F B= Il Typical magnetic field strengths: Earth’s field bar magnet B ~50 mT 0.1 T MRI magnet 0.2 – 3.0 T Electromagnetism Electric currents have loops of B flux around them. Current-turns produce flux. Magnetic fields near currents I • long straight wire B 2r 0 • long solenoid, N turns and length l N B I l 0 4 10 NA is the permeability of free space 7 -2 Forces on parallel currents parallel - attract anti-parallel - repel Forces on parallel currents At the top wire in the diagram, I B 2r F II BI l 2r 0 2 0 1 2 1 Defining the ampere (straight wires of infinite length) If the current in each wire is exactly 1 A, and the distance between the wires is 1 m, then the force on each metre length of the wires will be 2 x 10-7 N. Practice questions: TAP Forces on currents Force on a moving charge q F IlB lB qvB t F qvB sin Demonstration: fine beam tube • uniform B-field at right angles to an electron beam with v • F is perpendicular to v, so the beam travels in a circular path. mv qvB r 2 Fluxes and forces Michael Faraday (experimenting in 1830s at the Royal Institution) pictured magnetic field lines as flexible and elastic • magnetic attraction: field lines try to get shorter & straighter • magnetic repulsion: field lines cannot cross Faraday’s law of induction Induced emf is proportional to rate of ‘cutting’ field lines. N is number of turns on the secondary coil. N is its flux linkage. emf E = -N dF dt Induced emf is proportional to rate of change in coil’s flux linkage. NOTE: Eddy currents are induced in iron core linking primary and secondary coils. These can be reduced by laminations in core. dF dt can be: 1 the flux cut by a moving wire 2 the change in flux due to a magnet moving 3 the change in flux due to a stationary electromagnet which is changing in strength No relative motion means no induced emf. Under what conditions is there an induced current? Experiments • Force on a current-carrying wire • Current balance • Investigating fields near currents (using a Hall probe) • Investigating electromagnetic induction • Faraday’s law • Jumping ring Practice questions • (Adv Physics) Changes in flux linkage • (Adv Physics) Flux or flux linkage? • TAP Rates of change • (Adv Physics) Graphs of changing flux and emf Endpoints • rotating coil (AC) generator: emf • motors produce a ‘back emf’ BANcost