Magnetics 3 Question 11

11. A long horizontal wire $A B$, which is free to move in a vertical plane and carries a steady current of $20 A$, is in equilibrium at a height of $0.01 m$ over another parallel long wire $C D$ which is fixed in a horizontal plane and carries a steady current of $30 A$, as shown in figure. Show that when $A B$ is slightly depressed, it executes simple harmonic motion. Find the period of oscillations.

$(1994,6$ M)

$$ C \xrightarrow{A \longrightarrow} B $$

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Answer:

Correct Answer: 11. $0.2 s \quad$ 12. $\mathbf{F}=\frac{-\mu _0 I^{2}}{2 \pi} \ln \frac{L^{2}+a^{2}}{a^{2}} \hat{\mathbf{k}}$, zero

Solution:

  1. Let $m$ be the mass per unit length of wire $A B$. At a height $x$ above the wire $C D$, magnetic force per unit length on wire $A B$ will be given by

$$ F _m=\frac{\mu _0}{2 \pi} \frac{i _1 i _2}{x} \quad \text { (upwards) } $$

Weight per unit length of wire $A B$ is

$$ F _g=m g $$

(downwards)

Here, $m=$ mass per unit length of wire $A B$

At $\quad x=d$, wire is in equilibrium i.e.,

$$ \begin{array}{rlrl} F _m & =F _g \\ \text { or } \quad & \frac{\mu _0}{2 \pi} \frac{i _1 i _2}{d} & =m g \\ \text { or } \quad & \frac{\mu _0}{2 \pi} \frac{i _1 i _2}{d^{2}} & =\frac{m g}{d} \end{array} $$

When $A B$ is depressed, $x$ decreases therefore, $F _m$ will increase, while $F _g$ remains the same. Let $A B$ is displaced by $d x$ downwards.

Differentiating Eq. (i) w.r.t. $x$, we get

$$ d F _m=-\frac{\mu _0}{2 \pi} \frac{i _1 i _2}{x^{2}} \cdot d x $$

i.e. restoring force, $F=d F _m \propto-d x$

Hence, the motion of wire is simple harmonic.

From Eqs. (ii) and (iii), we can write

$$ d F _m=-\frac{m g}{d} \cdot d x \quad(\because x=d) $$

$\therefore$ Acceleration of wire $a=-\frac{g}{d} \cdot d x$

Hence, period of oscillation

$$ \begin{aligned} T & =2 \pi \sqrt{\left|\frac{d x}{a}\right|} \\ & =2 \pi \sqrt{\frac{\mid \text { displacement } \mid}{\mid \text { acceleration } \mid}} \\ T & =2 \pi \sqrt{\frac{d}{g}} \\ & =2 \pi \sqrt{\frac{0.01}{9.8}} \\ T & =0.2 s \end{aligned} $$

or



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