A 1-cm3 air bubble at a depth of 291 meters and at a temperature of 4 oC rises to the surface of the lake where the temperature is 10.4 oC, to the nearest tenth of a cm3, what is its new volume?
To calculate the pressure of a 1cm3 air bubble at 291m underwater, we can use the formula P = ρgh, where P is the pressure, ρ is the density of water, g is the acceleration due to gravity, and h is the depth. In this case, we would substitute the values for ρ (1000 kg/m3), g (9.8 m/s2), and h (291m) to calculate the pressure.
The density of water at a depth of 291m is approximately 1000 kg/m3. This value can vary slightly depending on factors such as temperature and salinity.
The pressure of a 1cm3 air bubble will increase as it descends to a depth of 291m. This is due to the increased weight of the water above the bubble, which causes an increase in pressure according to the formula P = ρgh.
The pressure of a 1cm3 air bubble at 291m would depend on the type of gas it is filled with. The formula P = ρgh can still be used, but the value for ρ would need to be adjusted based on the density of the gas. For example, a bubble filled with helium (ρ = 0.1785 kg/m3) would have a lower pressure at 291m compared to a bubble filled with air.
Yes, the formula P = ρgh can be used to calculate the pressure of any size air bubble at a depth of 291m. However, the pressure calculated would be for the entire volume of the bubble, not just a single 1cm3 section.