Yes, both liquids and gases exert a buoyant force on objects submerged or immersed in them. This force is a result of the pressure difference at various depths in the fluid medium, which ultimately supports the object's weight.
Yes, liquids and gases exert a buoyant force on objects placed in them due to the pressure difference at different depths. This force counteracts the weight of the object, causing it to float or rise in the fluid. The magnitude of the buoyant force is equal to the weight of the displaced fluid by the object.
Liquids such as water and gases such as air exert a buoyant force on objects placed in them. This force is a result of the pressure difference between the top and bottom of the object, pushing it upward.
Liquids and gases exert a buoyant force on objects due to the pressure differences in the fluid caused by the weight of the object displacing the fluid. This force is a result of Archimedes' principle, stating that the buoyant force is equal to the weight of the fluid displaced by the object.
True. Both liquids and gases exert a buoyant force on objects placed in them due to the difference in pressure at different depths. This force is what causes objects to float or sink in a fluid.
Gases exert a buoyant force because they are less dense than liquids or solids. When a gas is immersed in a fluid, the surrounding fluid exerts an upward force on the gas, pushing it upward. This buoyant force is a result of the difference in densities between the gas and the surrounding medium.
Both liquid and gas
Yes, liquids and gases exert a buoyant force on objects placed in them due to the pressure difference at different depths. This force counteracts the weight of the object, causing it to float or rise in the fluid. The magnitude of the buoyant force is equal to the weight of the displaced fluid by the object.
Liquids such as water and gases such as air exert a buoyant force on objects placed in them. This force is a result of the pressure difference between the top and bottom of the object, pushing it upward.
Liquids and gases exert a buoyant force on objects due to the pressure differences in the fluid caused by the weight of the object displacing the fluid. This force is a result of Archimedes' principle, stating that the buoyant force is equal to the weight of the fluid displaced by the object.
True. Both liquids and gases exert a buoyant force on objects placed in them due to the difference in pressure at different depths. This force is what causes objects to float or sink in a fluid.
Gases exert a buoyant force because they are less dense than liquids or solids. When a gas is immersed in a fluid, the surrounding fluid exerts an upward force on the gas, pushing it upward. This buoyant force is a result of the difference in densities between the gas and the surrounding medium.
yes, all fluids wether it is gas or liquid, will experience buoyant force.
Both liquids and gases exert a buoyant force on objects placed within them. This force depends on the density of the fluid and the volume of the object submerged. The buoyant force always acts in the opposite direction to gravity.
Gas expands while water doesn't if you have 8oz of water in a 10oz container then pour it in a 16oz the water will stay 8 oz
Gas is one of the states of matter. Matter has weight and takes up space. When rocket propellants are burned or oxidized, they give off expanding gases. Since gas is matter the expanding gases exert force.
the answer to thins question in inside your pants hahah but no its resistance
As a rocket burns fuel, it expels exhaust gases. When the gases are forced out of the rocket, they exert an equal and opposite force on the rocket. A rocket can rise into the air because the gases it expels with a downward force exert an equal but opposite force on the rocket. As long as this upward pushing force, called thrust, is greater than the downward pull of gravity, there is a net force in the upward direction. As a result, the rocket accelerates upwards.-information from Prentice Hall, Science Explorer: Physical Science