A bubble of radius R in water of density rho is expanding uniformly at speed v. Given that water is incompressible, the kinetic energy of

Q: A bubble of radius $R$ in water of density $\rho$ is expanding uniformly at speed $v$. Given that water is incompressible, the kinetic energy of water being pushed is

b $(b)$ Let bubble of radius $x$ expands and pushes water of density $\rho$ by a distance $d x$. Then, kinetic energy of water of strip $d x$ is $d K=\frac{1}{2} d m \cdot v_{x}^{2} \Rightarrow d K=\frac{1}{2} 4 \pi x^{2} \cdot d x \cdot \rho \cdot v_{x}^{2}$ or $d K=2 \pi R^{2} \cdot \rho \cdot v_{x}^{2} \cdot d x \quad \ldots$ $(i)$ Considering laminar flow, for section $1$ and $2$ shown in figure, by equation of continuity $A_{1} v_{1}=A_{2} v_{2} \Rightarrow 4 \pi x^{2} v_{x}=4 \pi R^{2} v$ $\Rightarrow \quad v_{x} =\frac{R^{2}}{x^{2}} \cdot v\quad \ldots$ $(ii)$ From Eqs. $(i)$ and $(ii)$, we have $d K=2 \pi x^{2} \rho\left(\frac{R^{2}}{x^{2}} \cdot v \cdot\right)^{2} d x$ $\Rightarrow d K=2 \pi R^{4} \rho v^{2} \cdot\left(\frac{d x}{x^{2}}\right)$ So, kinetic energy of complete volume of water, $K=\int \limits_{R}^{\infty} d K=2 \pi R^{4} \rho v^{2} \int \limits_{R}^{\infty} \frac{d x}{x^{2}}$ $\Rightarrow \quad K=2 \pi R^{4} \cdot \rho \cdot v\left[-\frac{1}{x}\right]_{R}^{\infty}$ $=2 \pi \rho R^{3} v^{2}$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

A bubble of radius $R$ in water of density $\rho$ is expanding uniformly at speed $v$. Given that water is incompressible, the kinetic energy of water being pushed is

A
zero
B$2 \pi \rho R^{3} v^{2}$
C$2 \pi \rho R^{3} v^{2} / 3$
D$4 \pi \rho R^{3} v^{2} / 3$

KVPY 2019, Advanced

STD 11 Science
NEET
STD 11 - 9.1. fluid mechanics
Physics

Download our app
and get started for free

Experience the future of education. Simply download our apps or reach out to us for more information. Let's shape the future of learning together!No signup needed.*

Download App

Similar Questions

1
Which of the following option correctly describes the variation of the speed $v$ and acceleration $'a'$ of a point mass falling vertically in a viscous medium that applies a force $F = -kv,$ where $'k'$ is a constant, on the body? (Graphs are schematic and not drawn to scale)
View Solution
2
A solid sphere, of radius $R$ acquires a terminal velocity $\nu_1 $ when falling (due to gravity) through a viscous fluid having a coefficient of viscosity $\eta $. The sphere is broken into $27$ identical solid spheres. If each of these spheres acquires a terminal velocity, $\nu_2$, when falling through the same fluid, the ratio $(\nu_1/\nu_2)$ equals
View Solution
3
$Assertion :$ For Reynold’s number $Re > 2000$, the flow of fluid is turbulent.
$Reason :$ Inertial forces are dominant compared to the viscous forces at such high Reynold’s numbers.
View Solution
4
If $W$ be the weight of a body of density $\rho $ in vacuum then its apparent weight in air of density $\sigma $ is
View Solution
5
Water flows steadily through a horizontal pipe of variable cross-section. If the pressure of water is $P$ at a point where flow speed is $v$ , the pressure at another point where the flow speed is $2v$ , is (Take density of water as $\rho $ )
View Solution
6
Water flows into a large tank with flat bottom at the rate of ${10^{ - 4}}\,{m^3}{s^{ - 1}}$. Water is also leaking out of a hole of area $1\, cm^2$ at its bottom. If the height of the water in the tank remains steady, then this height is........ $cm$
View Solution
7
The rate of steady volume flow of water through a capillary tube of length $ 'l' $ and radius $ 'r' $ under a pressure difference of $P$ is $V$. This tube is connected with another tube of the same length but half the radius in series. Then the rate of steady volume flow through them is (The pressure difference across the combination is $ P$)
View Solution
8
A cork is submerged in water by a spring attached to the bottom of a bowl. When the bowl is kept in an elevator moving with acceleration downwards, the length of spring
View Solution
9
A cork is submerged in water by a spring attached to the bottom of a pail. When the pail is kept in a elevator moving with an acceleration downwards, the spring length
View Solution
10
Two capillary tubes of same radius $r$ but of lengths $l_1$ and $l_2$ are fitted in parallel to the bottom of a vessel. The pressure head is $P$. What should be the length of a single tube that can replace the two tubes so that the rate of flow is same as before
View Solution

Download our appand get started for free

Similar Questions

Download our app
and get started for free