General Chemistry

Buffer Solution

Resists pH changes — weak acid + conjugate base maintains constant pH

A buffer solution resists changes in pH when small amounts of acid or base are added. Composition: weak acid + its conjugate base (or weak base + conjugate acid). Mechanism: weak acid neutralizes added base; conjugate base neutralizes added acid. Henderson-Hasselbalch equation: pH = pKa + log([A⁻]/[HA]). Critical in biology — blood (carbonic acid/bicarbonate), buffers in cells, lab work, industry. Buffer capacity highest near pKa; ratio [A⁻]/[HA] determines pH; absolute concentration determines capacity.

  • CompositionWeak acid + conjugate base (or weak base + conjugate acid)
  • Henderson-HasselbalchpH = pKa + log([A⁻]/[HA])
  • Best at pH near pKaHighest capacity within ~1 pH unit of pKa
  • Blood bufferCarbonic acid/bicarbonate (HCO₃⁻/H₂CO₃)
  • Buffer capacityDepends on absolute concentration
  • ExamplesAcetate, phosphate, ammonia, Tris, HEPES

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Why buffers matter

  • Biology. Blood pH maintenance.
  • Lab research. Constant pH for reactions.
  • Pharmaceuticals. Drug stability, IV solutions.
  • Industrial. pH control in processes.
  • Aquaculture. Maintaining stable pH for organisms.
  • Cosmetics. Skin-friendly products.
  • Food. Preservation, taste.

Common misconceptions

  • Buffers fully prevent pH change. Resist; not infinite capacity.
  • Higher pH means stronger buffer. Capacity = concentration; pKa near target.
  • Strong acids work as buffers. No — must be weak.
  • Buffer pH equals pKa always. Only when [A⁻] = [HA].
  • Adding water won't affect. Dilution reduces capacity.
  • Buffers always have pKa = pH. pH varies by ratio.

Frequently asked questions

How does a buffer work?

Contains comparable amounts of weak acid (HA) and conjugate base (A⁻). When base added (OH⁻): HA + OH⁻ → A⁻ + H₂O — consumes added base, doesn't change pH much. When acid added (H⁺): A⁻ + H⁺ → HA — consumes added acid. Effective until one component depleted (then capacity exceeded).

What's the Henderson-Hasselbalch equation?

pH = pKa + log([A⁻]/[HA]). Predicts pH from buffer composition. When [A⁻] = [HA]: pH = pKa. To make buffer at desired pH: choose acid with pKa near target pH; adjust ratio. Useful for: making buffers, predicting pH effects.

How do you make a buffer?

Two methods. (1) Mix weak acid and its salt: e.g., acetic acid + sodium acetate. (2) Partial neutralization: weak acid + strong base (e.g., HA + NaOH at 50% conversion gives buffer). Start with target pH; choose acid with pKa near it; calculate ratio from Henderson-Hasselbalch; mix appropriate amounts.

What's buffer capacity?

Amount of acid or base buffer can absorb without significant pH change. Higher capacity = larger concentrations of buffer components. Buffer at pH = pKa: maximum capacity (1:1 ratio resists addition best). Beyond capacity (ratio shifts to extremes): pH changes rapidly. Used in solutions where pH stability is critical.

How does blood maintain pH?

Multiple buffers. Most important: carbonic acid/bicarbonate (H₂CO₃/HCO₃⁻). pKa ≈ 6.1. Despite being far from blood pH 7.4, large bicarbonate concentration provides capacity. Plus: phosphate buffer (intracellular), proteins (histidine pKa ≈ 6.0). System: respiratory (CO₂ release controls H₂CO₃) and renal (kidney HCO₃⁻ regulation) work together.

What are common laboratory buffers?

Tris (pKa 8.1) — biology research, near physiological pH. HEPES (pKa 7.5) — biology, biological cell culture. Phosphate (pKa 7.2) — aqueous biology. Acetate (pKa 4.76) — moderately acidic. Citrate — wide pH range. Choose based on: pKa near desired pH, compatibility with experiment, low metal binding.

When does a buffer fail?

(1) Capacity exceeded: too much acid/base added → one component depleted → pH changes rapidly. (2) Outside ±1 pH unit from pKa: ratio extreme; small additions cause large changes. (3) Dilution: capacity reduced; in extreme dilution, water dominates pH. Solutions: increase concentrations or change buffer components.