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Magnetic Fields Due to Currents

Magnetic Fields Due to Currents. Chapter 29. Remember the wire?. Try to remember…. Coulomb. The “Coulomb’s Law” of Magnetism. The Law of Biot-Savart. A Vector Equation. For the Magnetic Field, current “elements” create the field. This is the Law of Biot-Savart. This is to calculate B!.

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Magnetic Fields Due to Currents

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  1. Magnetic Fields Due to Currents Chapter 29

  2. Remember the wire?

  3. Try to remember… Coulomb

  4. The “Coulomb’s Law” of Magnetism The Law of Biot-Savart A Vector Equation

  5. For the Magnetic Field,current “elements” create the field. This is the Law of Biot-Savart This is to calculate B!

  6. Magnetic Field of a Straight Wire • We intimated via magnets that the Magnetic field associated with a straight wire seemed to vary with 1/d. • We can now PROVE this!

  7. Using Magnets From the Past

  8. Directions: The Right Hand Rule Right-hand rule: Grasp the element in your right hand with your extended thumb pointing in the direction of the current. Your fingers will then naturally curl around in the direction of the magnetic field lines due to that element. Reminder !

  9. Let’s Calculate the FIELD Note: For ALL current elements in the wire: ds X r is into the page

  10. The Details

  11. Moving right along 1/d Verify this.

  12. Center of a Circular Arc of a Wire carrying current

  13. ds More arc…

  14. The overall field from a circular current loop

  15. Iron

  16. Howya Do Dat?? No Field at C

  17. Force Between Two Current Carrying Straight Parallel Conductors Wire “a” creates a field at wire “b” Current in wire “b” sees a force because it is moving in the magnetic field of “a”.

  18. The Calculation

  19. Invisible Summary • Biot-Savart Law • (Field produced by wires) • Centre of a wire loop radius R • Centre of a tight Wire Coil with N turns • Distance a from long straight wire • Force between two wires

  20. Ampere’s Law • The return of Gauss

  21. Remember GAUSS’S LAW?? Surface Integral

  22. Gauss’s Law • Made calculations easier than integration over a charge distribution. • Applied to situations of HIGH SYMMETRY. • Gaussian SURFACE had to be defined which was consistent with the geometry. • AMPERE’S Law is compared to Gauss’ Law for Magnetism!

  23. AMPERE’S LAWby SUPERPOSITION: We will do a LINE INTEGRATION Around a closed path or LOOP.

  24. Ampere’s Law USE THE RIGHT HAND RULE IN THESE CALCULATIONS

  25. The Right Hand Rule .. AGAIN

  26. Another Right Hand Rule

  27. COMPARE Line Integral Surface Integral

  28. Simple Example

  29. Field Around a Long Straight Wire

  30. Field INSIDE a WireCarrying UNIFORM Current

  31. The Calculation

  32. B R r

  33. Procedure • Apply Ampere’s law only to highly symmetrical situations. • Superposition works. • Two wires can be treated separately and the results added (VECTORIALLY!) • The individual parts of the calculation can be handled (usually) without the use of vector calculations because of the symmetry. • THIS IS SORT OF LIKE GAUSS’s LAW

  34. A Physical Solenoid

  35. Inside the Solenoid For an “INFINITE” (long) solenoid the previous problem and SUPERPOSITION suggests that the field OUTSIDE this solenoid is ZERO!

  36. More on Long Solenoid Field is ZERO! Field is ZERO Field looks UNIFORM

  37. The real thing….. Finite Length Weak Field Stronger Fairly Uniform field

  38. Another Way

  39. Application • Creation of Uniform Magnetic Field Region • Minimal field outside • except at the ends!

  40. Two Coils

  41. “Real” Helmholtz Coils Used for experiments. Can be aligned to cancel out the Earth’s magnetic field for critical measurements.

  42. The Toroid Slightly less dense than inner portion

  43. The Toroid

  44. 15.  A wire with current i=3.00 A is shown in Fig.29-46. Two semi-infinite straight sections, both tangent to the same circle, are connected by a circular arc that has a central angle θ and runs along the circumference of the circle. The arc and the two straight sections all lie in the same plane. If B=0 at the circle's center, what is θ?

  45. 38.  In Fig. 29-64, five long parallel wires in an xy plane are separated by distance d=8.00 cm , have lengths of 10.0 m, and carry identical currents of 3.00 A out of the page. Each wire experiences a magnetic force due to the other wires. In unit-vector notation, what is the net magnetic force on (a) wire 1, (b) wire 2, (c) wire 3, (d) wire 4, and (e) wire 5?

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