Well for example we put a ball filled with water, with a density of $1\cdot 10^3 kg/m^3$, in space.
How to calculate the pressure the water is exposed to?
Answer
Consider a ball of water floating in zero G, as demonstrated on the ISS. Ignoring for the moment the surface tension of the water (I'll come back to that) the pressure inside the water is the same as the pressure of the air around it. This is simply because without any forces, like gravity, acting on the water there is nothing to cause a pressure gradient.
Well the pressure isn't quite the same. In my first paragraph I mentioned that the air-water interface has a surface tension, and this acts a bit like the elastic of a balloon. It compresses the water inside the drop and increases the pressure slightly. The Hyperphysics site has an article deriving the pressure and the result is that the extra pressure is given by:
$$ \Delta P = \frac{2\gamma}{r} $$
where $\gamma$ is the surface tension, which is about 0.07 N/m for pure water, and $r$ is the radius of the ball of water. If we take a radius of 1 cm we get $\Delta P = 14$ Pa. This is negligable compared with the atmospheric pressure of $101,325$ Pa, so it's a very good approximation to say the pressure inside the ball of water is the same as the pressure of the air around it.
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