In water, every 10 meters you go down, the pressure increases by 1 bar, approximately. To this you must add the air pressure, which is also approximately 1 bar (depending on whether you want gauge pressure or absolute pressure).
At 30 meters depth in salt water, a diver will experience a pressure of approximately 4 atmospheres or 4 times the pressure at the surface. This is because water exerts 1 atmosphere of pressure for every 10 meters of depth.
This question is set up to trick you. You don't need to know how much water surrounds the dam, because it is irrelevant. Assuming the atmospheric pressure is the same for both dams, depth is the only factor that affects fluid pressure. It's simply evaluating your knowledge of basic hydrostatic principles. So, for any depth, these two lakes have no difference in pressure.
The pressure at a depth of 10 meters underwater is about 2 atmospheres, which is equivalent to around 1 atmosphere of pressure at the surface plus an additional atmosphere for every 10 meters of depth. This increased pressure is due to the weight of the water above pushing down on you.
The pressure exerted on a diver 10 m underwater is approximately 2 atmospheres or 1.8 times the atmospheric pressure at the surface. This means the pressure is effectively doubled at this depth.
The pressure at a depth of 200 feet of water is approximately 86.6 pounds per square inch (psi). This is calculated by dividing the depth (200 feet) by the specific gravity of water (0.433) to determine the pressure in psi.
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10.20 meters in depth
At 30 meters depth in salt water, a diver will experience a pressure of approximately 4 atmospheres or 4 times the pressure at the surface. This is because water exerts 1 atmosphere of pressure for every 10 meters of depth.
This question is set up to trick you. You don't need to know how much water surrounds the dam, because it is irrelevant. Assuming the atmospheric pressure is the same for both dams, depth is the only factor that affects fluid pressure. It's simply evaluating your knowledge of basic hydrostatic principles. So, for any depth, these two lakes have no difference in pressure.
Pressure in a fluid at a certain depth H is proportional to the density of the fluid. Since Mercury has a much higher density then water it will exert a much larger pressure at the same depth.
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The pressure at a depth of 10 meters underwater is about 2 atmospheres, which is equivalent to around 1 atmosphere of pressure at the surface plus an additional atmosphere for every 10 meters of depth. This increased pressure is due to the weight of the water above pushing down on you.
Atmospheric pressure is approximately equal to 14.7 pounds per square inch One bar is equal to one atmosphere
At a depth of 3,000 meters below water level, the pressure can be calculated using the formula: pressure = depth × density of water × gravitational acceleration. The average density of seawater is about 1,025 kg/m³, and gravitational acceleration is approximately 9.81 m/s². Thus, the pressure at this depth is roughly 30,000 kPa, or about 300 times atmospheric pressure (1 atm being approximately 101.3 kPa).
Yes, rock buried at depth can have a lower melting temperature due to increased pressure. The high pressure can stabilize minerals at lower temperatures compared to those found at the surface. This phenomenon is known as the geothermal gradient.
It's totally dependent on the hull type, material construction, and overall design, but in general, just before a submarine reaches crush depth is as much sea pressure as it can handle.