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Chapter 33. The Magnetic Field

Chapter 33. The Magnetic Field. 1. Moving charges make a magnetic field The magnetic field exerts a force on moving charges Thus moving charges exert forces on each other (Biot Savart Law) A collection of moving charges constitutes and electrical current

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Chapter 33. The Magnetic Field

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  1. Chapter 33. The Magnetic Field • 1. Moving charges make a magnetic field • The magnetic field exerts a force on moving charges Thus moving charges exert forces on each other (Biot Savart Law) • A collection of moving charges constitutes and electrical current • Currents exert forces and torques on each other

  2. * * This isn’t really true but pretend for the moment that it is.

  3. Magnetic Field Electric Field r What are the magnitudes and directions of the electric and magnetic fields at this point? Assume q > 0 q Comparisons: both go like r-2, are proportional to q, have 4p in the denominator, have funny Greek letters Differences: E along r, B perpendicular to r and v

  4. Electric Field points away from positive charge

  5. Magnetic field is perpendicular to

  6. Greek Letters Huh? These funny numbers are a consequence of us having decided to measure charge in Coulombs Later we will find:

  7. Same result as:

  8. The positive charge is moving straight out of the page. What is the direction of the magnetic field at the position of the dot? • Left • Right • Down • Up

  9. The positive charge is moving straight out of the page. What is the direction of the magnetic field at the position of the dot? • Left • Right • Down • Up

  10. Field near a point charge Field lines emerge from charges Iron filings align parallel to magnetic field Field lines do not end

  11. Electric field due to a dipole - two opposite charges separated by a distance Magnetic field due to a single loop of current

  12. Magnets are objects that have charges moving inside them Electrical currents

  13. Does the compass needle rotate clockwise (cw), counterclockwise (ccw) or not at all? • Clockwise • Counterclockwise • Not at all

  14. Does the compass needle rotate clockwise (cw), counterclockwise (ccw) or not at all? • Clockwise • Counterclockwise • Not at all

  15. Does the compass needle feel a force from the charged rod? • Attracted • Repelled • No force • Attracted but very weakly It’s complicated

  16. Does the compass needle feel a force from the charged rod? • Attracted • Repelled • No force • Attracted but very weakly It’s complicated

  17. z B = 1T in the y direction y 106 m/s in x-y plane x 60° What is the force on a moving electron? What is q in this problem? 60° 30° 72 ° and sunny

  18. Cyclotron Motion Newton’s Law Both a and F directed toward center of circle Equate

  19. In this picture B is pointing into the page and q is positive. What changes if q is negative and B points out of the page Rotation changes to counter-clockwise There is no change Why do things always have to change?

  20. In this picture B is pointing into the page and q is positive. What changes if q is negative and B points out of the page Rotation changes to counter-clockwise There is no change Why do things always have to change?

  21. Some Examples Ionosphere at equator ITER fusion exp

  22. y E . . x v z B Motion of a charged particle in crossed electric and magnetic fields Try these If vx=Ey/Bz force is zero and no acceleration Particle will move at a constant velocity in a direction perpendicular to both E and B

  23. Where are you most likely to encounter E cross B motion? Your doctor’s office Your Kitchen The bridge of the Starship Enterprise

  24. B-out of page Magnetron Electrons spiral out from the cathode K toward anode A. Potential energy is converted into radiation, f=2.45 GHz Radiation then converted into popcorn B, V0 and Slots in anode define radiation frequency Where are you most likely to encounter E cross B motion? Your doctor’s office Your Kitchen The bridge of the Starship Enterprise

  25. Current carrying wire Inside the wire there are stationary charges and moving charges. Metallic conductor Moving - free electrons Stationary - positive ions and bound electrons In any length of wire the number of positive and negative charges is essentially the same (unless the wire is charged). The wire can carry a current because the free electrons move.

  26. Number density, n, of free electrons is a property of the material. For copper Current, number density and velocity Consider a segment of length l, cross sectional area A A volume The segment has N free electrons Suppose the free electrons have speed v. How long will it take all the electrons to leave the segment?

  27. Current During a time interval Dt = l/v, a net charge Q = -eN flows through any cross section of the wire. The wire is thus carrying I The current is flowing in a direction opposite to that of v. A

  28. How big is v for typical currents in copper? Close to the speed of light Supersonic About as fast as a Prius Glacial A

  29. How big is v for typical currents in copper? Close to the speed of light Supersonic About as fast as a Prius Glacial A For a 1mm radius copper wire carrying 1 A of current

  30. What is the force on those N electrons? Force on a single electron Force on N electrons Now use points parallel to the wire in the direction of the current when I is positive Lets make l a vector Force on wire segment:

  31. Comments: Force is perpendicular to both B and l Force is proportional to I, B, and length of line segment Superposition: To find the total force on a wire you must break it into segments and sum up the contributions from each segment

  32. What is the force on a rectangular loop? Net force is zero

  33. Torque on a loop Plane of loop is tilted by angle q with respect to direction of B. The loop wants to move so that its axis and B are aligned. Definition of torque

  34. Nuclear magnetic resonance Basis of MRI magnetic resonance imaging

  35. Magnetic Field due to a current Magnetic Field due to a single charge If many charges use superposition r3 r2 #3 q3 , v3 Where I want to know what B is r1 #2 q2 , v2 #1 q1, v1

  36. For moving charges in a wire, first sum over charges in each segment, then sum over segments

  37. Summing over segments - integrating along curve Biot Savart law r I Integral expression looks simple but…..you have to keep track of two position vectors which is where you want to know B which is the location of the line segment that is contributing to B. This is what you integrate over.

  38. Magnetic field due to an infinitely long wire z Current I flows along z axis I I want to find B at the point x I will sum over segments at points

  39. 0 j See lecture notes

  40. r compare with E-field for a line charge

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