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MIT visualizations: Biot Savart Law, Integrating a circular current loop on axis

MIT visualizations: Biot Savart Law, Integrating a circular current loop on axis. Change of policy: Quizzes: you are allowed one 3x5 index card to write anything you wish on it, front and back. Coursemail

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MIT visualizations: Biot Savart Law, Integrating a circular current loop on axis

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  1. MIT visualizations: Biot Savart Law, Integrating a circular current loop on axis

  2. Change of policy: • Quizzes: you are allowed one 3x5 index card to write anything you wish on it, front and back. • Coursemail • If you did not receive the class e-mails, please give me an e-mail address after class! • Class e-mails are posted on the website – see the “Solutions/Class e-mails tab” link

  3. Notes on how to study: • Give a chapter a cursory read before lecture • Print out lecture notes ahead of class ( if available). Take notes on slides/back-side. • Notes on how to do homework: • Read some section(s) and take notes from book • Work those homework problems pertaining to section(s) away from computer! • Login to computer terminal and check answers • Spend a moment reflecting on the concepts the homework problem examined • Reiterate through out week and finish homework on time • Quizzes and Exams will presume know how to work all problems. • If you don't do the homework, you will be killed by exams and quizzes • Notes on how to study for quizzes: • Review homework and compare with posted solutions • Review your book notes + lecture notes • Write up your 3x5 card • Minimize memorization in many cases by remembering principle(s) + derivation • Notes on how to study for exams: • Review book notes + Lecture notes + the homework problems you have written

  4. Last time: • -Moving charges (and currents) create magnetic fields • -Moving charges (and currents) feel a force in magnetic fields • Defines the B-field; Examples - cyclotron frequency, velocity selector, • mass spectrometer - Force on a wire segment: - Force on a straight wire segment in uniform B-field: - Torque on current loop in uniform magnetic field: - Potential energy of magnetic dipole (current loop) in magnetic field

  5. The Source of the Magnetic Field: Moving Charges

  6. MIT Biot Savart visualization http://ocw.mit.edu/ans7870/8/8.02T/f04/visualizations/magnetostatics/03-CurrentElement3d/CurrentElement3d.htm

  7. Summary of three Right Hand Rules:

  8. Applying the Biot-Savart Law Arbitrary shaped currents difficult to calculate Simple cases, one can solve relatively easily with pen and paper: current loops, straight wire segments Last time, we found B-field for straight wire segment with current in x- direction: And limit xf=-xi=L-> infinity for an infinitely long straight wire:

  9. Applying the Biot-Savart Law: Circular arc  Circle

  10. http://ocw.mit.edu/ans7870/8/8.02T/f04/visualizations/magnetostatics/08-RingMagInt/MagRingIntFullScreen.htmhttp://ocw.mit.edu/ans7870/8/8.02T/f04/visualizations/magnetostatics/08-RingMagInt/MagRingIntFullScreen.htm http://ocw.mit.edu/ans7870/8/8.02T/f04/visualizations/magnetostatics/09-RingMagField/RingMagFieldFullScreen.htm

  11. Applying the Biot-Savart Law: On-axis of circular loop

  12. Applying the Biot-Savart Law: On-axis of circular loop

  13. Applying the Biot-Savart Law: On-axis of circular loop

  14. Ampere’s Law: An easier way to find B-fields (in very special circumstances)

  15. Ampere’s Law: An easier way to find B-fields (in very special circumstances)

  16. Ampere’s Law: An easier way to find B-fields (in very special circumstances)

  17. Ampere’s Law: An easier way to find B-fields (in very special circumstances) For any arbitrary loop (not just 2-D loops!): Ampere’s Law Use Ampere’s Law to find B-field from current (in very special circumstances) • Current that does not go through “Amperian Loop” does not contribute to the integral • Current through is the “net” current through loop • 3. Try to choose loops where B-field is either parallel or perpendicular to ds, the Amperian loop. To do this, remember that symmetry is your friend! • Review pages 850-853!!

  18. Ampere’s Law: Example, Finite size infinite wire Calculate the B-field everywhere from a finite size, straight, infinite wire with uniform current. From symmetry, Br=0 (reverse current and flip cylinder) Bz=0 (B=0 at infinity, Amperian rectangular loop from infinity parallel to axial direction implies zero Bz everywhere) Only azimuthal component exists. Therefore, amperian loops are circles such that B parallel to ds.

  19. Ampere’s Law: Example, Finite size infinite wire Calculate the B-field everywhere from a finite size, straight, infinite wire with uniform current.

  20. Ampere’s Law: Example, Finite size infinite wire Calculate the B-field everywhere from a finite size, straight, infinite wire with uniform current.

  21. Ampere’s Law: Example, Infinitely long solenoid • As coils become more closely spaced, and the wires become thinner, and the length becomes much longer than the radius, • The B-field outside becomes very, very small (not at the ends, but away from sides) • The B-field inside points along the axial direction of the cylinder • Symmetry arguments for a sheet of current around a long cylinder: • Br=0 – time reversal + flipping cylinder, but time reversal would flip Br! • Azimuthal component? No, since if we choose Amperian loop perpendicular to axis, no current pierces it. • B=0 everywhere outside: any Amperian loop outside has zero current through it

  22. Ampere’s Law: Example, Infinitely long solenoid Cross sectional view:

  23. Ampere’s Law: Example, Toroid Solenoid bent in shape of donut. B is circumferential.

  24. Force Between two parallel, straight current carrying wires: Parallel currents attract, Opposite currents repel.

  25. Permanent magnets related to (tiny) currents: Current loops look like magnets, and vice versa: Permanent magnets can be thought of as a many tiny current loops created by the ‘spin’ of the electron. These tiny current loops (magnetic moments) tend to line up creating a macroscopic, large magnetic field. Note that, at least from a classical point of view, a charged sphere spinning creates a circulating current  magnetic field.

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