The total pressure within a container of a mixture of gases is equal to the sum of the partial pressure of each gas.

The partial pressure of a gas is always less than the vapor pressure of water at the same temperature.

Dalton’s Law states that the pressure of a gas mixture is always less than the pressure of the most abundant gas.

Dalton’s Law applies only to solids and liquids, not gases.

Ptotal = 978 mm Hg

Ptotal = 800 mm Hg

Ptotal = 600 mm Hg

Ptotal = 500 mm Hg

PO2 = 0.17 atm

PO2 = 0.25 atm

PO2 = 0.10 atm

PO2 = 0.05 atm

PH2 = 2930 mm Hg

PH2 = 1250 mm Hg

PH2 = 4180 mm Hg

PH2 = 5500 mm Hg

Diffusion is the ability of a gas to spread out in all directions. Effusion is the rate at which a gas escapes from a tiny pinhole in a container.

Diffusion is the process of a liquid turning into a gas, while effusion is the process of a solid turning into a liquid.

Diffusion is the movement of solids through liquids, while effusion is the movement of liquids through solids.

Diffusion is the rate at which a gas escapes from a container, while effusion is the ability of a gas to spread out in all directions.

Rate A / Rate B = sqrt(MM_B / MM_A)

Rate A / Rate B = sqrt(MM_A / MM_B)

Rate A / Rate B = MM_A / MM_B

Rate A / Rate B = MM_B / MM_A

Higher molar mass: effusion rate is slower. Lower molar mass: effusion rate is faster.

Higher molar mass: effusion rate is faster. Lower molar mass: effusion rate is slower.

Molar mass does not affect the rate of effusion for a gas.

Both higher and lower molar mass gases effuse at the same rate.