Magnetic Field Due To A Current Loop.

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Presentation transcript:

Magnetic Field Due To A Current Loop. Today’s agenda: Magnetic Field Due To A Current Loop. You must be able to apply the Biot-Savart Law to calculate the magnetic field of a current loop. Ampere’s Law. You must be able to use Ampere’s Law to calculate the magnetic field for high-symmetry current configurations. Solenoids. You must be able to use Ampere’s Law to calculate the magnetic field of solenoids and toroids. You must be able to use the magnetic field equations derived with Ampere’s Law to make numerical magnetic field calculations for solenoids and toroids.

Magnetic Field of a Current Loop A circular ring of radius a carries a current I as shown. Calculate the magnetic field at a point P along the axis of the ring at a distance x from its center. Draw a figure. Write down the starting equation. It tells you what to do next. Draw a figure. Write down the starting equation. It tells you what to do next. y I a x x P z

Magnetic Field of a Current Loop A circular ring of radius a carries a current I as shown. Calculate the magnetic field at a point P along the axis of the ring at a distance x from its center. Complicated diagram! You are supposed to visualize the ring lying in the yz plane. y dl dB I  dBy 90- a dl is in the yz plane. r is in the xy plane and is perpendicular to dl.* Thus 90-  x x P dBx z Also, dB must lie in the xy plane* (perpendicular to dl) and is perpendicular to r. *Only when dl is centered on the y-axis!

By symmetry, By will be 0. Do you see why? dl dB I  dBy 90- a 90-  x x P dBx z By symmetry, By will be 0. Do you see why? Use symmetry to find By. Don’t try to integrate dBy to get By. See here for the reason.

y I dl dBy dBz x x P dBx z When dl is not centered at z=0, there will be a z-component to the magnetic field, but by symmetry Bz will be zero.

I, x, and a are constant as you integrate around the ring! dl dB I  dBy 90- a 90-  x x P dBx z I, x, and a are constant as you integrate around the ring! This is not on your starting equation sheet. I will add it if we have homework or a test problem where I judge that you need it.

At the center of the ring, x=0. y At the center of the ring, x=0. dl dB I  dBy 90- a 90-  x x P dBx z For N tightly packed concentric rings (a tight coil)… This is not on your starting equation sheet, but I will add it if we have homework or a test problem where I judge that you need it. For homework, if a problem requires this equation, you need to derive it!