An air bubble starts rising from the bottom of a lake. Its diameter is 3.6 mm at the bottom and 4mm at the surface. The depth of the lake is 250 cm and the temperature at the surface is `40^@C`. The atmospheric pressure is 76 cm of Hg and `g=980 cm.s^-2`.
What is the pressure at the bottom of the lake?

An air bubble starts rising from the bottom of a lake. Its diameter is 3.6 mm at the bottom and 4mm at the surface. The depth of the lake is 250 cm and the temperature at the surface is 40^@C . The atmospheric pressure is 76 cm of Hg and g=980 cm.s^-2 . What is the temperature at the bottom of the lake?

Surface of a lake is at 2^(@)C . Find the temperature of the bottom of the lake

An air bubble of volume 1.0 cm^3 rises from the bottom of a lake 40 m 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 ?

An air bubble floats up on the surface of water from the bottom of a river of depth 34 m. At the bottom the temperature of water is 7^@C and the volume of the bubble is 14 cm^3 Temperature on the surface of the water is 27^@C and the pressure is 75 cmHg. IF the density of mercury is 13.6 g.cm^-3 them what will be the volume of the bubble on the surface of water?

When an air bubble rises from the bottom of a lake to the surface,its radius is doubled. Atmospheric pressure is equal to the pressure of a water column of height H. Depth of the lake is

An air bubble of diameter 1 mm is formed at the bottom of a lake and when it rises to the surface of the water, its diameter becomes 2 mm. If the atmospheric pressure is 760 cm of mercury, then find the depth of the lake. (Density of mercury = 13.6g*cm^(-3) )

When an air bubble rises from the bottom of a lake to the surface, its radius, is doubled. Atmospheric pressure is equal' to the pressure of a water column of height it. Depth of the lake is-