Air exerts pressure in the same way that water exerts pressure on a diver. Air has weight, and because we are at the bottom of a blanket of air that surrounds the earth, the weight of that air is pressing down on us (creating pressure). If you go under water, you'll feel the additional pressure created by the weight of the water above you.
The pressure and volume are related because both are variable of indefinite which means that both are not positive or definite and they tend to vary by the object they are in.
Your ears pop on a mountain when there's a difference in air pressure between your inner ear and the air outside. The air in your inner ear exchanges pretty slowly. And since the air is much thinner at the top of the mountain than it is near the bottom, if you go down quickly enough (like by driving) the pressures can't equalize gradually. The higher pressure air at the bottom of the mountain presses on your eardrums until they "pop" and the pressure equalizes. That can hurt!
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.
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
There is no difference of the average local air pressure inside or outside of the headphone.
The relationship between altitude and air pressure is inverse: as altitude increases, air pressure decreases. This is because air pressure is a measure of the weight of air molecules above a given point, so as you go higher in the atmosphere, there are fewer air molecules above you exerting pressure downward.
The relationship between air pressure and windis that air from areas of higher pressure flow to areas of lower pressure, creating wind.
the sky
The main difference between the air below and above the wings of a plane in flight is the air pressure. The air below the wings has higher pressure, while the air above the wings has lower pressure. This pressure difference creates lift, allowing the plane to stay in the air.
The deeper you go, the more air is above you ... thus higher air pressure.
The relationship between storm intensity and air pressure is that as air pressure decreases, storm intensity typically increases. This is because lower air pressure allows for the formation of stronger winds and more severe weather conditions, leading to more intense storms.
The relationship between air pressure and a water tank is that the air pressure in the tank affects the flow and pressure of the water coming out of it. The air pressure in the tank helps to push the water out when a faucet is opened, creating a steady flow of water. If the air pressure in the tank is too low, the water flow may be weak or inconsistent.
Air pressure decreases as altitude increases.
Air travels from high to low pressure in the atmosphere during flight through the process of air movement known as wind. Wind is created by the pressure differences between high and low pressure systems, causing air to move from areas of high pressure to areas of low pressure. This movement of air helps to balance out the pressure differences in the atmosphere.
the higher you are, the higher the air pressure, thats why airoplanes cant go too high, there is less oxygen and more air pressure
The relationship between pressure and humidity in the atmosphere is that as air pressure increases, the capacity of the air to hold water vapor also increases. This means that higher pressure generally leads to higher humidity levels, while lower pressure typically results in lower humidity levels.
Lift is generated when air pressure differences are created above and below an aircraft's wings. The airfoil shape of the wings causes air to move faster over the top surface, resulting in lower pressure compared to the higher pressure beneath the wings. This pressure difference creates an upward force, or lift, allowing the aircraft to rise and stay aloft. Therefore, the relationship between lift and air pressure is fundamental to the principles of flight.