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Raoult's Law: Ideal Solution Vapor Pressure

Raoult's Law states P = x·P°: the partial vapor pressure of a component equals its mole fraction times its pure vapor pressure. Ideal solutions (e.g., benzene-toluene) obey this; non-ideal solutions show positive or negative deviations. Foundation for distillation and colligative properties.

Concept Fundamentals
P = x·P°
Raoult's Law
Ptotal = P₁ + P₂
Total Pressure
y = P/Ptotal
Vapor Composition
P = γ·x·P° (non-ideal)
Activity
Calculate Vapor PressureP = x·P° | Ideal solutions | Colligative properties

Why This Chemistry Calculation Matters

Why: Raoult's Law underpins vapor-liquid equilibrium, distillation design, and solution thermodynamics. Essential for chemical engineering separations and understanding colligative properties.

How: Enter mole fractions (summing to 1) and pure vapor pressures. For ideal solutions, P = x·P°. For non-ideal, use activity coefficients: P = γ·x·P°. Vapor composition follows Dalton's Law: y = P/Ptotal.

  • Ideal solutions: benzene-toluene, hexane-heptane; similar molecules.
  • Positive deviation (water-ethanol): weaker interactions than pure components.
  • Negative deviation (chloroform-acetone): stronger interactions (e.g., H-bonding).
Sources:IUPAC Gold BookNIST Chemistry WebBook

Solution Examples

💧 Water-Ethanol Ideal Solution

Equal mole fractions - ideal behavior

🧪 Benzene-Toluene Mixture

Classic ideal solution example

📈 Water-Ethanol Positive Deviation

Non-ideal solution with positive deviation

📉 Chloroform-Acetone Negative Deviation

Non-ideal solution with negative deviation

🌊 Pure Water

Single component - pure water vapor pressure

🍺 Methanol-Water Mixture

Alcohol-water binary system

⛽ Hexane-Heptane Ideal

Alkane mixture - nearly ideal

💨 Calculate Vapor Composition

Find vapor mole fractions using Dalton's Law

Calculate Vapor Pressure

Between 0 and 1
Between 0 and 1
Pure component vapor pressure
Pure component vapor pressure
Affects vapor pressure

For educational and informational purposes only. Verify with a qualified professional.

🔬 Chemistry Facts

📐

Raoult's Law: Pi = xi × P°i for ideal solutions.

— IUPAC

🌡️

Non-ideal: Pi = γi × xi × P°i; γ > 1 positive, γ < 1 negative deviation.

— IUPAC

💧

Vapor enriched in more volatile component (higher P°).

— NIST

⚗️

Benzene-toluene is classic ideal solution; water-ethanol shows positive deviation.

— NIST

What is Raoult's Law?

Raoult's Law describes the vapor pressure of ideal solutions. It states that the partial vapor pressure of each component in a solution is equal to the vapor pressure of the pure component multiplied by its mole fraction in the solution.

Pᵢ = P°ᵢ × xᵢ

Pᵢ = partial vapor pressure, P°ᵢ = pure component vapor pressure, xᵢ = mole fraction

How Does Raoult's Law Work?

Raoult's Law is based on the principle that in an ideal solution, the escaping tendency of molecules is proportional to their concentration. Pᵢ = P°ᵢ × xᵢ; P_total = P₁ + P₂.

When to Use Raoult's Law

Use for vapor-liquid equilibrium, distillation design, chemical engineering separation processes, and solution thermodynamics. Essential for binary mixtures and phase behavior.

Types and Key Concepts

Ideal solutions (benzene-toluene, hexane-heptane). Non-ideal: positive deviation (water-ethanol) or negative deviation (chloroform-acetone). Activity coefficients: Pᵢ = γᵢ × P°ᵢ × xᵢ.

Key Formulas

Raoult's LawPᵢ = P°ᵢ × xᵢ
Non-IdealPᵢ = γᵢ × P°ᵢ × xᵢ
Total PressureP_total = P₁ + P₂
Vapor Compositionyᵢ = Pᵢ / P_total

Practical Examples and Reference Data

ComponentFormulaP° (25°C, mmHg)Boiling Point (°C)Category
WaterH_{2}O23.8100Common
EthanolC_{2}H₅ ext{OH}5978.4Alcohols
MethanolCH_{3} ext{OH}12764.7Alcohols
BenzeneC₆H₆95.180.1Aromatics
TolueneC₇H₈28.4110.6Aromatics
AcetoneC_{3}H₆O23056.1Ketones
ChloroformCHCl_{3}19961.2Halocarbons
Carbon Tetrachloride ext{CCl}₄11476.7Halocarbons
Diethyl EtherC₄H_{1}_{0}O53734.6Ethers
HexaneC₆H_{1}₄15168.7Alkanes
HeptaneC₇H_{1}₆45.898.4Alkanes
OctaneC₈H_{1}₈14.1125.7Alkanes
Acetic AcidCH_{3} ext{COOH}15.7118.1Acids
Formic Acid ext{HCOOH}42100.8Acids
PyridineC₅H₅N20115.2Heterocycles
CyclohexaneC₆H_{1}_{2}97.680.7Cycloalkanes
TetrahydrofuranC₄H₈O14566Ethers
DichloromethaneCH_{2}Cl_{2}43539.8Halocarbons
Ethyl AcetateC₄H₈O_{2}9577.1Esters
IsopropanolC_{3}H₇ ext{OH}4482.6Alcohols

Practical Examples

Example: Benzene-Toluene Ideal Solution

Given:

  • Benzene: P° = 95.1 mmHg, x = 0.6
  • Toluene: P° = 28.4 mmHg, x = 0.4
  • Temperature: 25°C

Solution:

P_benzene = 95.1 × 0.6 = 57.1 mmHg

P_toluene = 28.4 × 0.4 = 11.4 mmHg

P_total = 57.1 + 11.4 = 68.5 mmHg

y_benzene = 57.1/68.5 = 0.833

Example: Water-Ethanol Positive Deviation

Given:

  • Water: P° = 23.8 mmHg, x = 0.5
  • Ethanol: P° = 59.0 mmHg, x = 0.5
  • γ_water = 1.2, γ_ethanol = 1.3

Solution:

P_water = 1.2 × 23.8 × 0.5 = 14.3 mmHg

P_ethanol = 1.3 × 59.0 × 0.5 = 38.4 mmHg

P_total = 52.7 mmHg

Higher than ideal (41.4 mmHg)

Limitations of Raoult's Law

  • Does not apply to solutions with very different molecular sizes, strong H-bonding, electrolytes, or high pressure
  • Assumes chemically similar components, random mixing, and constant temperature

📚 Official Data Sources

IUPAC Gold Book ↗
Raoult's law definition and solution thermodynamics
Updated: 2024
NIST Vapor Pressure Data ↗
Vapor pressure and thermodynamic data
Updated: 2025
Atkins Physical Chemistry ↗
Solution thermodynamics reference
Updated: 2024

⚠️ Disclaimer: This calculator uses IUPAC definitions for Raoult's law and solution thermodynamics. Vapor pressure data is approximate; for precise work consult IUPAC Gold Book, NIST Chemistry WebBook, and Atkins Physical Chemistry.

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