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Question
Derive an expression for the net torque on a rectangular current carrying loop placed in a uniform magnetic field with its rotational axis perpendicular to the field.
Solution
- Consider rectangular loop abcd placed in a uniform magnetic field `vec"B"` such that the sides ab and cd are perpendicular to the magnetic field `vec"B"` but the sides bc and da are not, as shown in figure (a) below:
Fig (a): Loop abcd placed in a uniform - The force `vec"F"_4` on side 4 (bc) will be `vec"F"_4` = Il2 B sin(90° - θ)
- The force `vec"F"_2` on side 2 (da) will be equal and opposite to `vec"F"_4` and both act along the same line. Thus, `vec"F"_2` and `vec"F"_4` will cancel out each other.
- The magnitudes of forces `vec"F"_1` and `vec"F"_3` on sides 1 (cd) and 3 (ab) will be Il1 B sin 90° i.e., Il1 B. These two forces do not act along the same line and hence they produce a net torque.
- This torque results into rotation of the loop so that the loop is perpendicular to the direction of `vec"B"`, the magnetic field.
Fig (b): Side view of the loop abcd at an angle θ - Now the moment arm is `1/2 (l_2 sintheta)` about the central axis of the loop. Hence, the torque τ due to forces `vec"F"_1` and `vec"F"_3` will be
τ = `("I l"_1 "B"1/2"l"_2 sintheta) + ("I l"_1 "B"1/2"l"_2 sintheta)`
= `"I" l""_1 "l"_2 "B" sin theta` - If the current-carrying loop is made up of multiple turns N, in the form of a flat coil, the total torque will be
τ' = `"N"tau = "NI""l"_1"l"_2 "B" sintheta`
τ' = (NIA)B sinθ; where A is the are enclosed by the coil = l1l2
This is the required expression.
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