A spherical air bubble is rising from the depth of a lake when pressure is P atm and temperature is T K. The percentage increase in its radius when it comes to the surface of lake will be: (Assume temperature and pressure at the surface to be respectively `2 TK` and `(P)/(4)`)

A spherical air bubble is rising from the depth of a lake when pressure is P atm and temperature is T K . The percentage increase in the radius when it comes to the surface of a lake will be (Assume temperature and pressure at the surface to be, respectively, 2T K and P//4 .)

At the bottom of a lake where temperature is 7^(0)C the pressure is 2.8 atmosphere. An air bubble of radius 1 cm at the bottom rises to the surface. Where the temperature is 27^(0)C . Radius of air bubble at the surface is

At constant temperature if an air bubble present at the bottom of a lake at 8 atm pressure and with radius 0.1 cm rises to the surface then its new radius will become

When a large bubble rises from the bottom of a lake to the surface its radius doubles. If atmospheric pressure is equal to that of column of water height H then the depth of lake is

What will happen to volume of a bubble of air found under water in a lake where temperature is 15^(@)C and the pressure is 1.5 atm, if the bubble rises to the surface where the temperature is 25^(@)C and the pressure is 1.0 atm?

A small bubble rises from the bottom of a lake, where the temperature and pressure are 8^(@)C and 6.0 atm , to the water's surface, where the temperature is 25^(@)C and pressure is 1.0 atm . Calculate the final volume of the bubble if its initial volume was 2mL .

A small bubble rises from the bottom of a lake, where the temperature and pressure are 8^(@) C and 6.4 atm , to the surface of the water , where the temperature is 25^(@) C and pressure is 1.0 atm . Calculate the final volume ("in mL") of the bubble if its initial volume was 2.1 mL . Strategy : The amount of gas in the bubble remains constant (n_(1) = n_(2)) but there is a change in all the three quantities p , V , and T . This suggests that we use the combined gas law. We tabulate what is known and what is asked for , solve the combined gas law for the unknown quantity V_(2) and substitute the known values.