What is the value of I3 for the given line integral and values of I2 and B?

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The line integral around the closed path is given as 1.79×10−5 Tm, with I2 set at 12 A. The initial calculation for I3 was incorrect due to a misunderstanding of the direction of the magnetic field contributions from I2. After applying Ampere's Law correctly and considering the direction of the magnetic fields, it was determined that I2's contribution is negative. The corrected formula for I3 is I3 = (B/Uo) + I2, resulting in a final value of 26.2 A, indicating that I3 flows into the page.
PolarBee
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Homework Statement


The value of the line integral around the closed path in the figure is 1.79×10−5 Tm .
https://session.masteringphysics.com/problemAsset/1385538/4/32-22.jpg
32-22.jpg
There is I2 and I3 inside the closed loop.
I2 = 12 A
What is I3?

Homework Equations


Amphere's Law: B = Uo I(enclosed)

The Attempt at a Solution


I rewrote the equation as B = Uo * (I2 + I3)
Solving for I3...
I3 = (B / Uo) - I2
Plugging in values,
1.79*10^-5 / (4*pi*10^-7) - 12 = 2.2 A
But this is not the right answer? I don't understand what is wrong.
 
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Investigate how the direction taken around the closed path for the line integral affects the results; Check the definition of Ampere's Law.
 
Using the right hand rule to check the direction of positive I, positive I points into the page, so the 12A is negative and, so I should add 12 instead of subtracting?
 
PolarBee said:
Using the right hand rule to check the direction of positive I, positive I points into the page, so the 12A is negative and, so I should add 12 instead of subtracting?
What you want to do is check the direction of the field lines produced by any currents inside the line integral's closed path. If they have the same sense (direction) as the Ampere Loop then they make a positive contribution to the sum. If they have the opposite sense then they make a negative contribution.

You have one given current, ##I_2##, and it comes out of the page. Do its magnetic field lines have the same sense as the loop direction?
 
Okay I see, so I2's field lines are opposite of the loop direction, so they make a negative contribution to the sum.

So it should be B = Uo (-I2 + I3)
Making I3 = (B/Uo) + I2

And I3 would be 26.2 A, and since it is positive it would be going into the page, correct?
 
Looks good!
 

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