A cylinder with a radius of $10 \;\mathrm{m}$ and a height of $10 \;\mathrm{m}$ is resting on top of a body of water. The cylinder is less dense than water. At the center of the base (equal to water level), a circular plane extends out to a radius of $100 \;\mathrm{m}$. At the end large circle, the surface curves upwards in a concave shape (imagine a sombrero with a vertical cylinder at the center).The base of the cylinder ($r= 10 \;\mathrm{m}$) is open to the water below it.
Water is added on top of the sombrero, forcing the object down into the water. The cylinder at the center has a volume $3140 \;\mathrm{m^3}$. That volume of water has a mass of $3140000 \;\mathrm{kg}$. The surface area of the large circle is $31400 \;\mathrm{m^3}$. Subtract the area of the cylinder ($314 \;\mathrm{m^3}$) and you have a total surface area of $31000 \ m^3$ on top of the sombrero. Add water until the sombrero is pushed down into the body of water (a depth of $1 \;\mathrm{m}$ of water has a mass of $3100000 \;\mathrm{kg}$ ). Water is displaced as the sombrero sinks until the downwards force is counteracted by buoyancy. Imagine there is no air in the cylinder and water is pressed against the top of the cylinder.
The atmosphere of the Earth pushes against the cylinder, sombrero, and the body of water. The top cylinder is now $9 \;\mathrm{m}$ above the body of water. Two meters below the top of the cylinder directly at the center, there is a mouth of a hose surrounded by water (mouth is facing downwards). This point is located $7 \;\mathrm{m}$ above the body of water. The hose extends outside the cylinder and leads over the edge of sombrero (imagine $101 \;\mathrm{m}$ away from center). This end of the hose is currently closed. Relative to the water level, this point is $5 \;\mathrm{m}$ above water level. The difference in height of the two ends is $2 \;\mathrm{m}$.
All of the sudden, the closed end transforms into an opening. The water at the end of the hose is now exposed to air at 1 atmosphere. Could you siphon water from the cylinder slowly where the water is replaced from the water from the base of the cylinder?
For example, $1 \;\mathrm{m^3}$ of water has a mass of $1000 \;\mathrm{kg}$. Water pressure is greater at the base of the cylinder than the top. Water is incompressible.