What is the Magnetic Field of a Toroidal Solenoid?

AI Thread Summary
A toroidal solenoid with inner radius 15.0 cm, outer radius 18.0 cm, 250 turns, and a current of 8.50 A was analyzed for magnetic field strength at various distances. The magnetic field is zero for distances less than the inner radius and greater than the outer radius due to the cancellation of currents in the solenoid's turns. When the distance is between the inner and outer radii, the magnetic field can be calculated using Ampere's Law. The discussion clarified that the current entering and exiting the surface of the amperian loop cancels out, resulting in no net enclosed current for distances beyond the outer radius. Understanding the current flow and its cancellation is crucial for determining the magnetic field in this scenario.
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Homework Statement



A toroidal solenoid has inner radius r1=15.0 cm and outer radius r2=18.0 cm. the solenoid has 250 turns and carries a current of 8.50 A. what is the magnitude of the magnetic field at the following distances from the center of the torus (a) 12.0 cm; (b) 16.0 cm; (c) 20.0 cm?


Homework Equations



Using Ampere's Law, B(2*pi*r) = \muNI

The Attempt at a Solution



The answer given is that if r < r1, the B is 0 as the I enclosed is 0.

However what i do not understand is that why is when r > r2, the I enclosed is also 0?
If r > r2, shouldn't the circle formed encompass the entire solenoid and thus all of the current?

Thanks.
 
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No. its because again the total current THROUGH the area is 0. current going inwards through one turn is canceled by the current coming outwards in the next turn. try to imagine, did you get it?
 
supratim1 said:
No. its because again the total current THROUGH the area is 0. current going inwards through one turn is canceled by the current coming outwards in the next turn. try to imagine, did you get it?

Not quite sure, but just to double confirm, is my representation of the amperian loop in red correct for r > r2? So do you mean that the current going into the page at the right hand side of the solenoid is canceled by the current coming out of the page on the left hand side?

[URL]http://img130.imageshack.us/i/solenoid.gif/[/URL]
 
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no. every turn's upper part cancels the current of the lower part. got it?
 
ok, i got it, apparently i got the magnetic field and the current flow mixed up.

So to summarise if the loop is bigger than r2, there will be a portion of the current flowing into the surface, and another equal portion coming out of the surface enclosed by the loop

And if the loop is between r1 and r2, then according to the diagram there will be just 1 portion of the current going into the surface and none out.
 

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