Abhishek is trying to solve this circuit question using Kirchhoff’s Voltage law.
And he arrives at this equation for the middle loop.
$(- I_{2} \times 6000) + (- I_{3} \times 3000) + (- I_{4} \times 4000) = 0$
Is he correct?

Yes

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Solution

The correct option is B No
Let’s try to apply Kirchhoff’s loop law to the middle loop. First let’s name the junctions.
Have named them A, B, C, D as you can see.

Let’s pick a junction and move around in a loop say ABCDA
(remember $Δ V = i r)$
On moving from A to B, as we move in the direction of current the potential decreases
so it’s $[- I 3 \times 3000]$ (following the convention where decrease in potential is negative and rise is positive)
On moving from B to C, as we move in the direction of current again the potential decreases
so it’s $[- I 4 \times 4000]$
On moving from C to D, as we move in the direction of current the potential should decrease but since R there is zero so the potential difference is also zero.
So it’s $[- I 3 \times 0] = 0$ .
On moving from D to A, as we move opposite to the direction of current the potential increases
so it’s $[+ I 2 \times 6000]$
So the equation becomes
$- I 3 \times 3000 - I 4 \times 4000 + 0 + I 2 \times 6000 = 0$
which is not same as the equation given in question ( check once!)
So it’s not correct!

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Similar questions

(- I_{2} \times 6000) + (- I_{3} \times 3000) + (- I_{4} \times 4000) = 0

(- I_{2} \times 6000) + (- I_{3} \times 3000) + (- I_{4} \times 4000) = 0

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I_{n} = \frac{π}{2} \int \frac{π}{4} {cot}^{n} x d x

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