Question 9

NUMERICALHARD

A tank contains two immiscible liquids of densities 6ρ6\rho and 2ρ2\rho. The higher density liquid is filled up to a height L/2L/2 from the bottom. A thin rod of density ρ\rho and length LL is fully immersed and hinged at the bottom so that it can oscillate freely, as shown in the figure. If the rod is slightly disturbed from its equilibrium, the time period of small oscillations is 2πnLg\frac{2\pi}{n} \sqrt{\frac{L}{g}}, where gg is the acceleration due to gravity. The value of nn is:

Question
Correct Answer: 1.73

Detailed Solution

To find the time period of small oscillations, we first determine the restoring torque acting on the rod when it is displaced by a small angle θ\theta from the vertical.

  1. Properties of the Rod: Let the cross-sectional area of the rod be AA. Mass of the rod, M=ρALM = \rho A L

Moment of inertia about the hinge at the bottom, I=13ML2=13(ρAL)L2=13ρAL3I = \frac{1}{3} M L^2 = \frac{1}{3} (\rho A L) L^2 = \frac{1}{3} \rho A L^3

  1. Torque due to Gravity: Gravity acts at the center of mass (L/2L/2 from the bottom).

τg=MgL2sinθ(ρAL)gL2θ=12ρAL2gθ\tau_g = Mg \frac{L}{2} \sin \theta \approx (\rho A L) g \frac{L}{2} \theta = \frac{1}{2} \rho A L^2 g \theta

This torque is destabilizing (tending to increase θ\theta).

  1. Torque due to Buoyancy: The rod is in two liquids. The bottom half (00 to L/2L/2) is in liquid of density 6ρ6\rho. The top half (L/2L/2 to LL) is in liquid of density 2ρ2\rho.

Buoyant force on lower part: Fb1=(6ρ)(AL2)g=3ρALgF_{b1} = (6\rho) (A \frac{L}{2}) g = 3\rho A L g, acting at a distance L/4L/4 from the hinge.

Torque τb1=Fb1L4θ=(3ρALg)L4θ=34ρAL2gθ\tau_{b1} = F_{b1} \frac{L}{4} \theta = (3\rho A L g) \frac{L}{4} \theta = \frac{3}{4} \rho A L^2 g \theta

Buoyant force on upper part: Fb2=(2ρ)(AL2)g=ρALgF_{b2} = (2\rho) (A \frac{L}{2}) g = \rho A L g, acting at a distance (L2+L4)=3L4(\frac{L}{2} + \frac{L}{4}) = \frac{3L}{4} from the hinge.

Torque τb2=Fb23L4θ=(ρALg)3L4θ=34ρAL2gθ\tau_{b2} = F_{b2} \frac{3L}{4} \theta = (\rho A L g) \frac{3L}{4} \theta = \frac{3}{4} \rho A L^2 g \theta

Total restoring torque from buoyancy: τb=τb1+τb2=34ρAL2gθ+34ρAL2gθ=32ρAL2gθ\tau_b = \tau_{b1} + \tau_{b2} = \frac{3}{4} \rho A L^2 g \theta + \frac{3}{4} \rho A L^2 g \theta = \frac{3}{2} \rho A L^2 g \theta

  1. Net Restoring Torque:

τnet=τbτg=(3212)ρAL2gθ=ρAL2gθ\tau_{net} = \tau_b - \tau_g = (\frac{3}{2} - \frac{1}{2}) \rho A L^2 g \theta = \rho A L^2 g \theta

  1. Equation of Motion: Id2θdt2=τnetI \frac{d^2\theta}{dt^2} = -\tau_{net}

13ρAL3d2θdt2=ρAL2gθ\frac{1}{3} \rho A L^3 \frac{d^2\theta}{dt^2} = -\rho A L^2 g \theta

d2θdt2=3gLθ\frac{d^2\theta}{dt^2} = -\frac{3g}{L} \theta

This is SHM with ω2=3gL    ω=3gL\omega^2 = \frac{3g}{L} \implies \omega = \sqrt{\frac{3g}{L}}.

The time period is: T=2πω=2πL3g=2π3LgT = \frac{2\pi}{\omega} = 2\pi \sqrt{\frac{L}{3g}} = \frac{2\pi}{\sqrt{3}} \sqrt{\frac{L}{g}}

Comparing with the given form T=2πnLgT = \frac{2\pi}{n} \sqrt{\frac{L}{g}}, we find:

n=31.732n = \sqrt{3} \approx 1.732

Rounding off to two decimal places, n=1.73n = 1.73.

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