Sound of wavelength $λ$ passes through a Quincke's tube, which is adjusted to give a maximum intensity $I_{o} .$ The two interfering waves have equal Intensities. Find the minimum distance the sliding tube should be moved to give an intensity $\frac{I_{o}}{2} .$

\frac{λ}{8}

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\frac{λ}{2}

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\frac{λ}{4}

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\frac{3 λ}{2}

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Solution

The correct option is A $\frac{λ}{8}$
The maximum intensity occurs during constructive interferece in Quincke's tube.

For two wave interference, we know that,

$I_{r} = I_{1} + I_{2} + 2 \sqrt{I_{1} I_{2}} cos ϕ . . . . . . . . . . (1)$

But, given that $I_{1} = I_{2} = I (say)$

So, $I_{m a x} = 4 I [∵ ϕ = 0]$

From the data given in the question,

$I = \frac{I_{m a x}}{4} = \frac{I_{o}}{4} . . . . . . . . . (2)$

Given that, required intensity $I_{r} = \frac{I_{o}}{2}$

From $(1)$ we can write that,

$\frac{I_{o}}{2} = I + I + 2 \sqrt{I \times I} cos ϕ$

Using $(2)$ in the above equation we get,

$cos ϕ = \frac{\frac{I_{o}}{2} - \frac{I_{o}}{2}}{2 \sqrt{\frac{I_{o}}{4}} \sqrt{\frac{I_{o}}{4}}} = 0$

$\Rightarrow ϕ = \frac{(2 n - 1) π}{2} where n = 1, 2, 3, 4.....$

We know that,
Path difference $(Δ x) = \frac{λ}{2 π} \times$ Phase difference $(ϕ)$
$∴ Δ x = \frac{λ}{2 π} \times \frac{(2 n - 1) π}{2} = \frac{(2 n - 1) λ}{4}$

For two successive points of constructive interference, in Quincke's tube, the path difference $Δ x = 2 x$ , where $x$ is the distance moved by tube.

So, the minimum distance the sliding tube should be moved is,
for $n = 1$ , $x = (\frac{Δ x}{2}) = \frac{λ}{8}$

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Sound of wavelength λ passes through a Quincke's tube, which is adjusted to give a maximum intensity Io. The two interfering waves have equal Intensities. Find the minimum distance the sliding tube should be moved to give an intensity Io2.

Sound of wavelength $λ$ passes through a Quincke's tube, which is adjusted to give a maximum intensity $I_{o} .$ The two interfering waves have equal Intensities. Find the minimum distance the sliding tube should be moved to give an intensity $\frac{I_{o}}{2} .$