ConductScienceConductScience

Buffer Recipe Calculator

Calculate buffer recipes with temperature-corrected pKa and ionic strength. PBS, Tris, HEPES, MOPS, and 8 more systems. Data never leaves your browser.

12 Buffer SystemsTemperature CorrectionReady Recipes

Try it out

Load example buffer data to see the full workflow

Standard 1× PBS. Adjust NaCl for non-standard ionic strength.

mM
mL
°C
pH Scale
TargetpKa
7.40
024678101214

Recipe

pKa7.200at 25°C
I0.1620M
ReagentFormulaMWMass (g)Vol (mL)
Sodium dihydrogen phosphateNaH₂PO₄119.980.4642
Disodium hydrogen phosphateNa₂HPO₄141.960.8704
Sodium chlorideNaCl58.448.0063
Potassium chlorideKCl74.550.2013

Preparation

  1. 1Weigh or measure all reagents for 1 L final volume.
  2. 2Dissolve in ~800 mL of deionized water (80% of final volume).
  3. 3Adjust pH to 7.40 at 25°C using a calibrated pH meter.
  4. 4Bring to final volume of 1 L with deionized water.
  5. 5Mix well and verify pH before use.
  • Calculate buffer recipes for PBS, Tris, HEPES, MOPS, and other common buffers
  • Adjust recipes for specific pH targets with temperature-corrected pKa
  • Compute ionic strength and account for salt contributions
  • Scale recipes between different volumes
  • Prepare buffers for protein, nucleic acid, or cell culture work

Don't use for

  • Organic solvent buffers (different pKa behavior)
  • Buffers outside pH 2-12 range
  • High-concentration buffers where activity coefficients matter significantly

How Buffers Work

A buffer is a solution that resists pH changes when small amounts of acid or base are added. It consists of a weak acid and its conjugate base (or a weak base and its conjugate acid) in equilibrium.

The Henderson-Hasselbalch equation describes this equilibrium: pH=pKa+log[A][HA]\text{pH} = \text{p}K_a + \log\frac{[A^-]}{[HA]}. At the pKa, equal concentrations of acid and base form are present, and the buffer has maximum capacity.

Buffers are most effective within ±1 pH unit of their pKa. Outside this range, the ratio of acid to base becomes so skewed that the buffer loses its ability to neutralize added acid or base.

Temperature Effects on Buffer pH

All buffer pKa values change with temperature, but the magnitude varies dramatically. Tris buffers are notorious — a Tris-HCl buffer prepared at pH 7.5 at room temperature (25°C) will be pH 8.0 at 4°C and pH 7.2 at 37°C.

Good's buffers (HEPES, MOPS, MES) were specifically designed for minimal temperature sensitivity. HEPES, for example, shifts only −0.014 pH units per °C — five times less than Tris.

This calculator applies temperature corrections automatically. Enter your working temperature, and the recipe will produce the correct pH at that temperature — not just at 25°C.

Choosing the Right Buffer System

Select a buffer whose pKa is within ±1 pH unit of your target pH. Beyond that, consider:

• Cell culture: HEPES or MOPS (low temperature sensitivity, non-toxic to cells) • Protein work: Tris (but prepare at working temperature) or phosphate (stable, but precipitates some metals) • Electrophoresis: TAE (better for cloning — DNA recovery) or TBE (sharper bands, higher resolution) • Low pH: Acetate (pH 3.7–5.6) or citrate (pH 3.0–6.2) • High pH: Carbonate-bicarbonate (pH 9.2–10.8)

Avoid phosphate buffers when working with divalent cations (Ca²⁺, Mg²⁺) — they form insoluble precipitates. Use Good's buffers instead.

Frequently Asked Questions

Next Steps

pH Meters

Benchtop and portable pH meters for buffer verification

Browse →

Analytical Balances

Precision balances for reagent weighing

Browse →

Need Help?

Get a quote on equipment or talk to our team.

Request quote →