The Art and Science of Traditional Soap-Making

Animal fats like beef tallow (composed of triglycerides: glycerol + three fatty acids) were heated with lye (often wood-ash-derived potassium hydroxide or sodium hydroxide). The reaction split triglycerides into glycerol and fatty acid salts (soap):

$$\text{Triglyceride}+3\text{NaOH}\to \text{Glycerol}+3\text{Sodium Fatty Acid Soaps}$$.

This process, though not fully understood chemically at the time, was optimized through trial and error

• Charring: High NaOH concentrations caused excessive heat, leading to fat decomposition rather than saponification.
• Insoluble Salts: Concentrated lye produced poorly soluble sodium salts, creating a barrier that hindered further reactions.
• Diffusion Issues: High surface tension in strong lye reduced NaOH’s ability to penetrate tallow, while early soap formation created a protective layer around unreacted fat.
• Equilibrium Shift: Excess NaOH shifted the reaction equilibrium backward, reducing efficiency.

Soapmakers found weaker lyes (e.g., potassium-rich wood ash lye or sodium carbonate) more effective:

• Slower Reaction: Allowed better control and reduced side reactions like charring12.
• Homogeneous Mixing: Improved contact between lye and fat, ensuring consistent saponification.