Partial pressure of gases

partial pressure, law of partial pressures, or Dalton's law was proposed by the scientist John Dalton, which carried out several meteorological studies and related to the composition of atmospheric air. According to him,

“partial pressure is the force that the molecules of a gas exert on the walls of a container, which is exactly the same as it would exert if it were in a gas mixture.”

Based on this conclusion, Dalton stated that the pressure exerted by a gas mixture (Total pressure, Pt) in the walls of a container is equal to the sum of the individual partial pressures of each of the gases that comprise this Mix.

P_t =P_THE + P_B + P_Ç

In which,

P_THE = partial pressure of gas A
P_B = partial pressure of gas B
P_Ç = partial pressure of gas C

For example, if we have a mixture formed by hydrogen gases (H₂), oxygen (O₂) and carbon dioxide (CO₂) inside a container, the pressure of this mixture is the result of the sum of the pressures of each of these gases, thus:

P_t =P_H2 + P_O2 + P_CO2

1- Relation of partial pressure to total pressure

According to John Dalton, the relationship between partial pressure of a certain gas (P_THE) with the total pressure of the gas mixture is always equal to molar fraction (X_THE) of gas, which results in the following formula:

P_THE = X_THE
P_t

It is noteworthy that the molar fraction of a gas is given by the relationship between the number of moles (nA) of this gas by the mole number (nt) of the gaseous mixture (resulting from the sum of the mole number of all the gases that make up the mixture).

X_THE = no_THE
no_t

Thus, if we substitute the formula for the molar fraction of the gas in the expression of the relationship between partial pressures, we have:

P_THE = no_THE
P_t no_t

2- Total pressure of a gas mixture

The total pressure of a gas mixture can be found not only by adding the partial pressures of the gases that make it up. It can be calculated using the clapeyron equation:

P_t.V_t = n_t.R.T

This formula can be used to calculate the total pressure, as long as the volume of the container (or the total volume of gases) and the total mol number (n) are used._t), being:

R = general gas constant
T = temperature of the mixture in Kelvin

Note: If the temperature is in degrees Celsius, change it to Kelvin; to do this just add the value provided with 273.

3- Example of application of partial pressure of a gas

Example: (FEI SP) In a 44.8L container, kept at 273K, 4 mol of hydrogen gas and 6 mol of oxygen gas in CNTP were mixed. Partial pressures of H₂ it's the₂, in atmospheres, are, respectively:

a) 1.0 and 2.0

b) 3.0 and 4.5

c) 0.8 and 1.2

d) 1.0 and 1.5

e) 2.0 and 3.0

Data provided by the exercise:

Temperature = 273 K
System volume = 44.8 L
Number of moles of hydrogen gas = 4 moles
Number of moles of oxygen gas = 6 moles

P_H2= ?

P_O2= ?

1^O Step: Calculate the total mole number

no_t = n_H2 + n_O2

no_t = 4 + 6

no_t = 10 mol

2^O Step: Calculate the total pressure (Pt) of the system using the Clapeyron equation

P_t.V_t = n_t.R.T

P_t.44,8 = 10.0,082.273

P_t.44,8 = 223,86

P_t = 223,86
44,8

P_t = 4.996875 atm, then P_t it's about 5 atm

3^O Step: Calculate the partial pressure of hydrogen gas

P_H2 = no_H2
P_t no_t

P_H2 =  4
 5 10

P_H2.10 = 4.5

P_H2.10 = 20

P_H2 = 20
10

P_H2 = 2 atm

4^O Step: Calculate the partial pressure of oxygen gas

As we have only two gases in the mixture and we know the pressure of one of them and the total pressure, to calculate the partial pressure of the oxygen gas, just use the expression of the total pressure of the mixture:

P_t =P_H2 + P_O2

5 = 2 + P_O2

P_O2 = 5 – 2

P_O2 = 3 atm

By Me. Diogo Lopes Dias