A spherical ball of radius `3.0xx10^(-4)` m and density `10^(4) kgm^(-3)` falls freely uner gravity through a distacne h before enternig a tank of water. If after enering the water the velocity of the ball does not change, what is the value of h (Viscosity of water is `9.8xx10^(-6) Nsm^(-2))`.

A spherical ball of radius 3.0xx10^(-4) m and density 10^(4) kg//m^(3) falls freely under gravity through a distance h before entering a tank of water. If after entering the water the velocity of the ball does not change, find h. Viscosity of water is 9.8xx10^(6) N-s//m^(2) .

A spherical ball of radius 3xx10^(-4) m and density 10^(4)kg//m^(3) falls freely under gravity through a distance h before entering a tank of water. If after entering the water the velocity of the ball does not change, find h the viscosity of water is 9.8xx10^(-6)N-s//m^(2)

In an experiment to verify Stokes law , a small spherical ball of radius r and density rho falls under gravity through a distance h in air before entering a tank of water. If the terminal velocity of the ball inside water is same as its velocity just before entering the water surface , then the value of h is proportional to : ( ignore viscosity of air ) .

A ball of radius r and density ρ falls freely under gravity through a distance h before entering water. Velocity of ball does not change even on entering water. If viscosity of water is eta the value of h is given by (##DPP_PHY_CP09_E01_002_Q01.png" width="80%">

A metallic sphere of radius 1.0 xx 10^(-3) m and density 1.0 xx 10^(4) kg//m^(3) enters a tank of water, after a free fall through a distance of h in the earth's gravitational field. If its velocity remains unchanged after entering water, determine the value of h . Given: coefficient of viscosity of water = 1.0 xx 10^(-3) N s//m^(2), g = 10ms^(-12) and density of water = 1.0 xx 10^(3) kg//m^(3) .

Neglecting the density of air, the terminal velocity obtained by a raindrop of radius 0.3 mm falling through the air of viscosity 1.8 xx10^(-5) N//m^(2) will be

Neglecting the density of air, the terminal velocity obtained by a raindrop of radius 0.3 mm falling through the air of viscosity 1.8 xx10^(-5) N//m^(2) will be

Find the volume density of the elastic deformation energy in fresh water at a depth of h = 1 m. (Bulk modulus of water = 2 xx 10^(9) N//m^(2) )

A spherical ball of diameter 1 cm and density 5xx10^(3)kg m^(-3) is dropped gently in a large tank containing viscous liquid of density 3xx10^(3)kgm^(-3) and coefficient of viscosity 0.1 Nsm^(-2) . The distance that the ball moves n 1 s after attaining terminal velocity is (g=10ms^(-2))

A smooth spherical ball of radius 1cm and density 4xx10^(3)kg//m^(3) is dropped gently in a large container containing viscous liquid of density 2xx10^(3)kg//m^(3) , and eta=0.1 N-s//m^(2) . The distance moved by the ball in t=0.1sec after it attains terminal velocity is