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Exam 2 is Tuesday Oct. 27 5:30-7 pm, Birge 145

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Presentation on theme: "Exam 2 is Tuesday Oct. 27 5:30-7 pm, Birge 145"— Presentation transcript:

1 Exam 2 is Tuesday Oct. 27 5:30-7 pm, Birge 145
Students w / scheduled academic conflict please stay after class TODAY to arrange alternate time. Covers: all material since exam 2 Book sections: Chap 27, 29, 30 (not 30.7), 31, , Bring: Calculator One (double-sided) 8 1/2 x 11 note sheet Exam review: Thursday, Oct. 22, in class Tue. Oct. 20, 2009 Physics 208 Lecture 14

2 Last time… RC circuits Magnetic fields Magnetic forces
Tue. Oct. 20, 2009 Physics 208 Lecture 14

3 Magnetic force on electric charges
Effect of uniform B-field on charged particle Charged particle not moving no effect Charged particle is moving: Force is perpendicular to Magnetic Field Particle Velocity Depends on sign of charge Tue. Oct. 20, 2009 Physics 208 Lecture 14

4 Magnetic force on charged particle
Magnitude of force is proportional to Charge of particle, q Speed of particle, v Strength of magnet field, B sin(), =angle between and Direction of force is perpendicular to both and vector ‘cross product’ Tue. Oct. 20, 2009 Physics 208 Lecture 14

5 FB on a Charge Moving in a Magnetic Field, Formula
FB = q v x B FB is the magnetic force q is the charge v is the velocity of the moving charge B is the magnetic field SI unit of magnetic field: tesla (T) CGS unit: gauss (G): 1 T = 104 G (Earth surface 0.5 G) Tue. Oct. 20, 2009 Physics 208 Lecture 14

6 Quick Quiz The three charges below have equal charge and speed, but are traveling in different directions in a uniform magnetic field. Which particle experiences the greatest magnetic force? B 1 2 3 1 2 3 All same F = q v B sin(q) Tue. Oct. 20, 2009 Physics 208 Lecture 14

7 Quick Quiz The three charges below have equal charge and speed, but are traveling in different directions in a uniform magnetic field. The force on all the particles is in the same direction. B 1 2 3 True False All forces are into page Magnitude F = q v B sin(q) Tue. Oct. 20, 2009 Physics 208 Lecture 14

8 Force on moving charged particle
intermediate Tue. Oct. 20, 2009 Physics 208 Lecture 14

9 Field direction notation
Field direction indicated by vector In-plane : draw vector Not in-plane : into-page out-of-page Tue. Oct. 20, 2009 Physics 208 Lecture 14

10 More force examples Force from B-field on moving charged particle
x x x x x x v B q ® ® ® ® ® v B q ­ ­ ­ ­ ­ ­ ­ ­ v B q F F F = 0 Units: 1 T (tesla) = 1 N / Am 1G (gauss) = 10-4 T Tue. Oct. 20, 2009 Physics 208 Lecture 14

11 Magnetic Force on a Current
Force on each charge Force on length of wire Force on straight section of wire, length L N Current Magnetic force S Magnetic field Tue. Oct. 20, 2009 Physics 208 Lecture 14

12 ‘Homopolar’ motor Why does the motor turn?
Electric Coulomb force pushes on magnet Magnetic field pushes on current from battery Current from battery heats the magnet Current through wire produces magnetic field Tue. Oct. 20, 2009 Physics 208 Lecture 14

13 Electric current produces magnetic field
Current (flow of electric charges ) in wire produces magnetic field. That magnetic field aligns compass needle Current Magnetic field Tue. Oct. 20, 2009 Physics 208 Lecture 14

14 Law of Biot-Savart B out of page Each element of current produces a contribution to the magnetic field. r I ds dI dB r = permeability of free space r = distance from current element Tue. Oct. 20, 2009 Physics 208 Lecture 14

15 Magnetic field from long straight wire: Direction
y What direction is the magnetic field from an infinitely-long straight wire? x I Tue. Oct. 20, 2009 Physics 208 Lecture 14

16 Magnetic field from a current
Iron filings align with magnetic field lines Magnetic field loops around the current. Tue. Oct. 20, 2009 Physics 208 Lecture 14

17 Forces between currents
Which of these pairs of currents will attract each other? A A & C B A & B Do demo of current carrying wires forcing each other apart. A B C Tue. Oct. 28, 2008 Physics 208, Lecture 17

18 Force between current-carrying wires
Attractive for parallel currents. Repulsive for antiparallel currents Tue. Oct. 28, 2008 Physics 208, Lecture 17

19 Current dependence How does the magnitude of the B-field change if the current is doubled? y Is halved Quadruples Stays same Doubles Is quartered x I Tue. Oct. 20, 2009 Physics 208 Lecture 14

20 Distance dependence How does the magnitude of the B-field at 2 compare to that at 1? y 2 B2=B1 B2=2B1 B2=B1/2 B2=4B1 B2=B1/4 1 x I Tue. Oct. 20, 2009 Physics 208 Lecture 14

21 Why? Biot-Savart says Why B(r) 1/r instead of 1/r2 ?
Small contribution from this current element. ~ independent of r Large contribution from this current element. Decreases as 1/r2 I Tue. Oct. 20, 2009 Physics 208 Lecture 14

22 Long straight wire All current elements produce B out of page
Add them all up: r a x Tue. Oct. 20, 2009 Physics 208 Lecture 14

23 Field from a circular loop
Each current element produce dB All contributions add as vectors Along axis, all components cancel except for x-comp Tue. Oct. 20, 2009 Physics 208 Lecture 14

24 Magnetic field from loop
Bz Which of these graphs best represents the magnetic field on the axis of the loop? A. z Bz B. z z x y Bz C. z Bz D. z Tue. Oct. 20, 2009 Physics 208 Lecture 14

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