User:R0ck$/Relative lowering of vapor pressure

Due to the dilution of the solvent, a lesser number of solvent particles are present on the surface of the solution. The surface of the solution acts as an interface between the vapor phase above it and the solution in the liquid phase. As a result of the increase in solute concentration, the solvent does not escape into the vapor phase, and this decreases the vapor pressure of the solvent.

The solvation of the solute in the solvent requires energy. Energy is expended in creation of a cavity and separation of solute particle from the bulk. These are not spontaneous processes. This expense of energy reduces the amount of energy available to the solvent particles to transform into a gas. Since fewer particles receive energy energy equivalent to their enthalpy of vaporization, the vapor pressure decreases.

For an ideal solution, the equilibrium vapor pressure is given by Raoult's law as ${\displaystyle p=p_{A}^{\star }x_{A}+p_{B}^{\star }x_{B}+\cdots ,}$  where ${\displaystyle p_{i}^{\star }}$  is the vapor pressure of the pure component ( ${\displaystyle i}$  = A, B, ...) and ${\displaystyle x_{i}}$  is the mole fraction of the component in the solution.

For a solution with a solvent (A) and one non-volatile solute (B), ${\displaystyle p_{B}^{\star }=0}$  and ${\displaystyle p=p_{A}^{\star }x_{A}}$ .

The vapor pressure lowering relative to pure solvent is ${\displaystyle \Delta p=p_{A}^{\star }-p=p_{A}^{\star }(1-x_{A})=p_{A}^{\star }x_{B}}$ , which is proportional to the mole fraction of solute.

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