An inverted vessel (bell) lying at the bottom of a lake, 47.6 m deep, has 50 cc of air trapped in it. The bell is brought to the surface of the lake. What will be the volume of the air trapped in it now, if temperature remains constant? (Atmospheric pressure = 70 cm of Hg and density of Hg = `13.6` g/cc) express it as `( x xx 100)`.

An air bubble rises from the bottom of a water tank of height 5 m. If the initial volume of the bubble is 3" mm"^(3) , then what will be its volume as it reaches the surface? Assume that its temperature does not change. [g=9.8m//s^(2),1" atm "=10^(5)” Pa, density of water"=1" gm"//"cc"]

An air bubble of volume 1.0 cm^(3) rises from the bottom of a lake 40m deep at a temperature of 12^(@)C . To what volume does it grow when it reaches the surface, which is at a temperature of 35^(@)C ?

Gases best follow the facts given below A) An ideal gas obeys the mathematical relation PV=nRT B) Rates of diffusion of two gases are in the reciprocal ratio of square roots of their molecular weight C) Total pressure of a mixture of non reacting gases is given by the algebric sum of their partial pressure An ideal gas is captured in a glass tube of uniform arca of cross section by a water column at a given temperature as shown If the tube is held vertical, by what length the water column descends down? (Density of mercury=13.6gm/cc) (P_(atm)=76cm of Hg)

What is the excess pressure inside a bubble of soap solution of radius 5.00 mm. given that the surface tension of soap solution at the temperature (20^@C) is 2.50 times 10^-2 N m^-1 ? If an air bubble of the same dimension were formed at depth of 40.0 cm inside a container the soap solution (of relative density 1.20] what would be the pressure inside the bubble?[1 atmospheric pressure is 1.01 times 10^5 Pa ).

What is the rate at which a trapped bubble of 2 mm diameter rises slightly through a solution of density 13.6 xx 10^3 kg//m^3 and coefficient of viscosity 1.5 centipoise ? Assume, the density of air is negligible and g = 10 m//s^2 .