3 atmospheres
Compared to 101 kiloPascals (kPa) at sea level, she would experience 87.9 kPa.
The equation is P1V1=P2V2. (P1 is pressure before the change, P2 is the pressure after, V1 is the volume before the change, and V2 is the volume after it.) So to solve it, it would be the same change no matter how much the volume and pressure were to begin with. The values are P1= 1 atmosphere (the pressure of air at sea level) V1= 1 Liter which would mean P2=3 atmospheres 1*1=3(V2) 1/3 Liter= V2. So the volume would be one third of what it was before the pressure was tripled.
You get a pressure of about 1 atmosphere (or bar) for every 10 meters.Note:The pressure has nothing to do with the volume of water behind it.It only depends on the depth or head.1 meter = 9,794.7 pa35 meters = 342.815 kpa35 meters = 114.83 feet = 49.72 psiThese figures are only for water in the tank.
The dependent variable would be blood pressure. The independent variable would be age. Of course, there are many factors, other than just age, which determine blood pressure.
atmosphere
One atmosphere is the amount of pressure that can lift water approximately 10.3 meters.Considering that a diver already experiences 1 ATM of pressure in air, the water depth in meters d, at which the diver would experience n ATM of pressure, isd = (n - 1) * 10.3Hence, to experience 3 atmospheres of pressure, you'd need to go ((3-1) * 10.3) = 20.6 meters (67.6 feet) underwater.
At 4 meters below the sea level, the pressure exerted by the water column above the diver would be approximately 0.4 atmospheres higher than atmospheric pressure at the surface. Therefore, the expected pressure of air in the diver's lungs would be the sum of this increase and atmospheric pressure.
You would blow up from water pressure.
The pressure in Earth's atmosphere is roughly equal to that of Mars at an altitude of about 30 kilometers (18.6 miles) above sea level. This means that if you were at this altitude on Earth, you would experience a similar atmospheric pressure to that on the surface of Mars.
A diver's ears can be hurt during a deep dive due to changes in pressure. As a diver descends, the pressure increases, causing the eardrum to push inward. Failure to equalize the pressure by clearing the ears can lead to barotrauma, causing pain, discomfort, and potentially injury.
Stuart diver may or may not have a diary but many people who have exsperienced it would know the story and Stuart also has writen a few books about his experience
If an astronaut were to enter Venus' atmosphere, they would experience extreme heat and pressure. The temperature on Venus can reach up to 900 degrees Fahrenheit (475 degrees Celsius), which is hotter than the surface of Mercury. The atmospheric pressure on Venus is about 92 times greater than Earth's, equivalent to being around 900 meters (3,000 feet) deep in the ocean. The high temperatures and pressure, combined with the thick carbon dioxide atmosphere, would make it impossible for a human to survive without adequate protection.
If Earth's atmosphere contained twice as many molecules as it does today, the atmospheric pressure would also double. This is because pressure is directly related to the number of gas molecules in the atmosphere.
It would be the barometric pressure of the atmosphere which depends on the altitude of the person in question.
the air pressure would increase because the amount of atmosphere above you increases
In dry air, nitrogen constitutes about 78% of the atmosphere by volume. Therefore, at 1 atmosphere pressure, the partial pressure of nitrogen would be 0.78 atm. This is calculated by multiplying the total pressure by the mole fraction of nitrogen in air.
To find the partial pressure of nitrogen, you first need to calculate the total pressure exerted by the atmosphere due to nitrogen. Since nitrogen makes up 78% of the atmosphere, you would multiply the total atmospheric pressure (749 mm Hg) by 0.78 to get the partial pressure of nitrogen, which would be 585.22 mm Hg.