361399 The velocity of rain drop having radius 1 \(mm\) is \({20 {~cm} {~s}^{-1}}\). The velocity of raindrops of size 3 \(mm\) is

361400 An air bubble of radius \(1\;cm\) rises from the bottom portion through a liquid of density \(1.5\,g\,c{c^{ - 1}}\) at a constant speed of \(0.25{\mkern 1mu} {\mkern 1mu} cm\,{s^{ - 1}}.\) If the density of air is neglected, the coefficient of viscosity of the liquid is approximately (in \(P a\) ).

361401 Spherical particles of pollen are shaken up in water and allowed to settle. The depth of water is \(2 \times {10^{ - 2}}\;m\). What is the diameter of the largest particles remaining in suspension one hour later? Density of pollen \( = 1.8 \times {10^3}kg{m^{ - 3}}\), viscosity of water \(=1 \times 10^{-2}\) poise and density of water \( = 1 \times {10^3}\;kg\;{m^3}\).

361402 A spherical body falling through a viscous liquid of infinite extent ultimately attains a constant value of velocity then

361403 A rain drop of radius \(0.3\;\,mm\) falling vertically downwards in air has a terminal velocity of 1 \(m/s\). The viscosity of air is \(18 \times 10^{-5}\) poise. The viscous force on the drop is

361399 The velocity of rain drop having radius 1 \(mm\) is \({20 {~cm} {~s}^{-1}}\). The velocity of raindrops of size 3 \(mm\) is

361400 An air bubble of radius \(1\;cm\) rises from the bottom portion through a liquid of density \(1.5\,g\,c{c^{ - 1}}\) at a constant speed of \(0.25{\mkern 1mu} {\mkern 1mu} cm\,{s^{ - 1}}.\) If the density of air is neglected, the coefficient of viscosity of the liquid is approximately (in \(P a\) ).

361401 Spherical particles of pollen are shaken up in water and allowed to settle. The depth of water is \(2 \times {10^{ - 2}}\;m\). What is the diameter of the largest particles remaining in suspension one hour later? Density of pollen \( = 1.8 \times {10^3}kg{m^{ - 3}}\), viscosity of water \(=1 \times 10^{-2}\) poise and density of water \( = 1 \times {10^3}\;kg\;{m^3}\).

361402 A spherical body falling through a viscous liquid of infinite extent ultimately attains a constant value of velocity then

361403 A rain drop of radius \(0.3\;\,mm\) falling vertically downwards in air has a terminal velocity of 1 \(m/s\). The viscosity of air is \(18 \times 10^{-5}\) poise. The viscous force on the drop is

361399 The velocity of rain drop having radius 1 \(mm\) is \({20 {~cm} {~s}^{-1}}\). The velocity of raindrops of size 3 \(mm\) is

361400 An air bubble of radius \(1\;cm\) rises from the bottom portion through a liquid of density \(1.5\,g\,c{c^{ - 1}}\) at a constant speed of \(0.25{\mkern 1mu} {\mkern 1mu} cm\,{s^{ - 1}}.\) If the density of air is neglected, the coefficient of viscosity of the liquid is approximately (in \(P a\) ).

361401 Spherical particles of pollen are shaken up in water and allowed to settle. The depth of water is \(2 \times {10^{ - 2}}\;m\). What is the diameter of the largest particles remaining in suspension one hour later? Density of pollen \( = 1.8 \times {10^3}kg{m^{ - 3}}\), viscosity of water \(=1 \times 10^{-2}\) poise and density of water \( = 1 \times {10^3}\;kg\;{m^3}\).

361402 A spherical body falling through a viscous liquid of infinite extent ultimately attains a constant value of velocity then

361403 A rain drop of radius \(0.3\;\,mm\) falling vertically downwards in air has a terminal velocity of 1 \(m/s\). The viscosity of air is \(18 \times 10^{-5}\) poise. The viscous force on the drop is

361399 The velocity of rain drop having radius 1 \(mm\) is \({20 {~cm} {~s}^{-1}}\). The velocity of raindrops of size 3 \(mm\) is

361400 An air bubble of radius \(1\;cm\) rises from the bottom portion through a liquid of density \(1.5\,g\,c{c^{ - 1}}\) at a constant speed of \(0.25{\mkern 1mu} {\mkern 1mu} cm\,{s^{ - 1}}.\) If the density of air is neglected, the coefficient of viscosity of the liquid is approximately (in \(P a\) ).

361401 Spherical particles of pollen are shaken up in water and allowed to settle. The depth of water is \(2 \times {10^{ - 2}}\;m\). What is the diameter of the largest particles remaining in suspension one hour later? Density of pollen \( = 1.8 \times {10^3}kg{m^{ - 3}}\), viscosity of water \(=1 \times 10^{-2}\) poise and density of water \( = 1 \times {10^3}\;kg\;{m^3}\).

361402 A spherical body falling through a viscous liquid of infinite extent ultimately attains a constant value of velocity then

361403 A rain drop of radius \(0.3\;\,mm\) falling vertically downwards in air has a terminal velocity of 1 \(m/s\). The viscosity of air is \(18 \times 10^{-5}\) poise. The viscous force on the drop is

361399 The velocity of rain drop having radius 1 \(mm\) is \({20 {~cm} {~s}^{-1}}\). The velocity of raindrops of size 3 \(mm\) is

361400 An air bubble of radius \(1\;cm\) rises from the bottom portion through a liquid of density \(1.5\,g\,c{c^{ - 1}}\) at a constant speed of \(0.25{\mkern 1mu} {\mkern 1mu} cm\,{s^{ - 1}}.\) If the density of air is neglected, the coefficient of viscosity of the liquid is approximately (in \(P a\) ).

361401 Spherical particles of pollen are shaken up in water and allowed to settle. The depth of water is \(2 \times {10^{ - 2}}\;m\). What is the diameter of the largest particles remaining in suspension one hour later? Density of pollen \( = 1.8 \times {10^3}kg{m^{ - 3}}\), viscosity of water \(=1 \times 10^{-2}\) poise and density of water \( = 1 \times {10^3}\;kg\;{m^3}\).

361402 A spherical body falling through a viscous liquid of infinite extent ultimately attains a constant value of velocity then

361403 A rain drop of radius \(0.3\;\,mm\) falling vertically downwards in air has a terminal velocity of 1 \(m/s\). The viscosity of air is \(18 \times 10^{-5}\) poise. The viscous force on the drop is