Lever Rule Calculator

Formulas

The formulas to calculate the mole fraction of each phase are:

\[ Xₐ = \frac{B - T}{B - A} \]

\[ X_b = \frac{T - A}{B - A} \]

Where:

\( Xₐ \) is the mole fraction of phase A
\( X_b \) is the mole fraction of phase B
\( A \) is the composition of phase A (in mole fraction or mass fraction)
\( B \) is the composition of phase B (in mole fraction or mass fraction)
\( T \) is the overall system composition (in mole fraction or mass fraction)

What is the Lever Rule?

The Lever Rule is a tool used in thermodynamics to determine the mole fraction (or mass fraction) of each phase of a binary equilibrium phase diagram. It is based on the principle of conservation of mass and is called the “Lever Rule” because it can be visually represented as a lever on a fulcrum, where the lengths of the lever arms are inversely proportional to the amounts of the phases present.

Example Calculation

Let's assume the following values:

Composition of Phase A (A) = 0.2
Composition of Phase B (B) = 0.8
Overall System Composition (T) = 0.5

Using the formulas to calculate the mole fractions:

\[ Xₐ = \frac{0.8 - 0.5}{0.8 - 0.2} = \frac{0.3}{0.6} = 0.5 \]

\[ X_b = \frac{0.5 - 0.2}{0.8 - 0.2} = \frac{0.3}{0.6} = 0.5 \]

The mole fractions of Phase A (Xₐ) and Phase B (X_b) are both 0.5.