Can Ampere's Law Still Apply When Whole Solenoid Is Enclosed?

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SUMMARY

Ampere's Law remains applicable even when the Amperian surface is a rectangle enclosing an entire solenoid. The key factor is that while the magnetic field outside an ideal solenoid is zero, the enclosed current still contributes to the magnetic field inside. When evaluating the integral of the magnetic field (B) along the sides of the rectangle, the contributions from the sides parallel to B yield a non-zero value, while the perpendicular sides contribute zero. Thus, the law holds true due to the enclosed current, which maintains the validity of the equation.

PREREQUISITES
  • Understanding of Ampere's Law and its mathematical formulation
  • Familiarity with magnetic fields and solenoids
  • Knowledge of vector calculus, specifically line integrals
  • Concept of ideal solenoids and their magnetic properties
NEXT STEPS
  • Study the derivation and applications of Ampere's Law in various geometries
  • Learn about the properties of ideal solenoids and their magnetic fields
  • Explore vector calculus techniques, particularly line integrals in electromagnetism
  • Investigate the relationship between enclosed current and magnetic fields in different configurations
USEFUL FOR

Physics students, electrical engineers, and anyone studying electromagnetism, particularly those interested in the applications of Ampere's Law in complex scenarios.

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Homework Statement


I want to know why Ampere's Law can sitll be applied/valid if the Amperian surface is drawn as a rectangle which encloses a whole solenoid. Normally the rectangle would just include one side of the solenoid.


Homework Equations





The Attempt at a Solution



When only one side of the solenoid is enclosed, Ampere's Law will work because B and ds will be parallel on the side of the rectangle which is inside the solenoid so we can intergrate this to an non-zero value. But I'm confused about when the whole solenoid is enclosed by the rectangle. It is an ideal solenoid so there should be no magnetic field outside the solenoid so the integral of the 2 sides which are parallel to B will be 0. The other two sides are perpendicular to B so they will also = 0. The only reason I can think that Ampere's Law still applies is that all of the current is enclosed so that somehow helps with the solution?

I'm really stuck here, because I keep getting the left side of the equation =0 so I cannot see how the law is still valid.
 
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Anyone?
 
Remember that current has a direction. You have to consider not only how much current goes through the rectangle, but in which direction it goes through.
 
But I thought it only depended on the direction of B and ds for the left side of the laW?
 
So the current travels in opposite directions on opposite sides of the rectangle and therefore the current will cancel out? So when we evaluate each side of the rectangle with the intergral involving B and ds we are supposed to get 0 because the right side of the equation is also supposed to equal zero?
 

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