All directions equally. Think of how a balloon blows up..... It expands with equal force all across the area of the balloon.
Gases behave differently at different pressures and temperatures. At low pressures, gases expand to fill the available space. At high pressures, gases become more compact. At low temperatures, gases condense into liquids or solids. At high temperatures, gases expand and exert greater pressure.
Dalton's law of partial pressures states that in a mixture of gases, the partial pressure of each is the same as that gas would exert if it were alone in the same volume.
No it does notIt may change direction but obviosly it cannot exert you force
D. Particles exert attractive forces. In real gases, the particles do not always move in the same direction, have the same kinetic energy, or have difficulty diffusing due to interactions between the particles leading to attractive forces that are not present in ideal gases.
Higher pressures this gives more collisions which is a goal of the gases
total pressure = sum of all partial pressures.
What are two examples of how the solubility of gases increases at higher pressures?Read more: What_are_two_examples_of_how_the_solubility_of_gases_increases_at_higher_pressures
What are two examples of how the solubility of gases increases at higher pressures?Read more: What_are_two_examples_of_how_the_solubility_of_gases_increases_at_higher_pressures
Direction
At increasing pressures the solubilty of gases is greater.
The total pressure of a gas mixture is the sum of the individual pressures.
If you exert a force on an object in motion you will change its velocity, velocity being a vector quantity of speed and direction.