There is air pressure on all sides, inside or outside. The air pressure pushes on the object all ways and nothing falls. If you only apply pressure on the bottom then the object will lift. If you apply pressure on the top, the object will collapse. If air pressure is pushing side ways, the object will move sideways.
Equal pressure inside us.
because the pressure is the same on the outside and inside of can making the can staying the same and not being crushed
The empty soda can is not sealed so air is free to enter and leave the can. As a result, pressure inside the can is the same as it is outside.
The very similiar effect that causes a nuclear exposion, but not to that effect. The air is removed creating a vacuum but there cannot be empty space so the air stretches to fill the void. Now if the metal can is sturdy enough to hold up enough pressure, the air molecules will stretch so far that they split apart, therefore causing a nuclear explosion. Please don't try this.
if the dna sequence of a gene was tacttaccgagctagact then what kind of mutation has occured This has nothing to do with the question of air pressure. Either a change of temperature or a change of volume can affect air pressure, according to Boyle's Law of Gases. Increasing temperature=increased air pressure Decreased volume=increased air pressure The reverse is also true. Decreased temperature=decreased air pressure Increased volume=decreased air pressure
Air pressure can crush objects like a desk because the weight of the air above the object creates a force pushing down on it. As the air pressure increases, this force becomes stronger, causing the object to collapse under the weight.
Yes it can. Depending on the range of air pressure between earth and space
Air pressure WILL crush objects. A standard experiment is to fill a 1 gallon can with water, and then closely fit a small diameter hose to the outlet. Invert the can, and if your hose was indeed sufficiently small, the water will drain out, and the can will collapse due to the air pressure from outside overcoming the strength of the can walls. Air pressure will not crush solid objects in general for they are already as dense as they can become.
Every day objects are surrounded by air, on all sides and inside, so all the force of the weight of the air acts equally in all directions.
Because that air pressure is the same on all sides and inside objects. If you were to seal a container at the top of Mt. Everest, Then took it down to Sea Level, It might crush (depending on the strength of the container) because the air pressure inside would be much less (the same as at the Peak where you sealed it) then it is at sea level.
The can is designed to withstand the external air pressure. When a can is sealed, the pressure inside and the pressure outside are balanced. However, when the can is empty and open, the pressure inside and outside the can equalize, preventing the can from being crushed.
The air pressure inside the can is equal to the external air pressure, so there is no imbalance causing the can to be crushed. The rigidity of the can also helps maintain its shape as the external air pressure decreases while driving down the mountain.
To conduct a can crush science experiment demonstrating air pressure principles, follow these steps: Fill a can with a small amount of water and heat it on a stove until steam comes out of the opening. Quickly place the can upside down in a bowl of cold water. The sudden cooling of the steam inside the can creates a vacuum, causing the atmospheric pressure outside the can to crush it. This experiment shows how changes in air pressure can affect everyday objects like cans.
Air pressure can be used to crush a can by heating the can and then quickly cooling it, causing the air inside to contract and create a lower pressure than the air outside. The higher outside air pressure then crushes the can.
Air pressure pushes equally on all sides of the can, so the pressure from the outside and inside of the can is balanced, preventing it from being crushed. Without any changes in pressure or force acting on the can, it remains in its original shape.
Air pressure can be used to crush a can by creating a difference in pressure inside and outside the can. When the can is heated and then quickly cooled, the air inside the can condenses, creating a lower pressure. The higher pressure outside the can then crushes it.
When a can is crushed, the air pressure inside the can decreases, causing the higher air pressure outside the can to crush it.