Species Distribution vs pH


Chemical context

Species distribution indicates which protonation state dominates at a specific pH. In polyprotic systems, equilibrium shifts stepwise with pKa values.

\[ \alpha_i = \frac{c_i}{C_T} \]

Fractions \(\alpha_i\) are dimensionless and always sum to 1. This is useful for buffer design, separations, and selecting reaction windows in analytical workflows.

Formulas (MathJax)
\[ K_{a,i}=10^{-\mathrm{p}K_{a,i}},\quad [H^+]=10^{-\mathrm{pH}} \]
\[ \alpha_0+\alpha_1+\alpha_2(+\alpha_3)=1 \]
\[ \text{Diprotic: }D=[H^+]^2+K_{a1}[H^+]+K_{a1}K_{a2} \]
\[ \alpha_0=\frac{[H^+]^2}{D},\;\alpha_1=\frac{K_{a1}[H^+]}{D},\;\alpha_2=\frac{K_{a1}K_{a2}}{D} \]
\[ \text{Triprotic: }D=[H^+]^3+K_{a1}[H^+]^2+K_{a1}K_{a2}[H^+]+K_{a1}K_{a2}K_{a3} \]
\[ \alpha_0=\frac{[H^+]^3}{D},\;\alpha_1=\frac{K_{a1}[H^+]^2}{D},\;\alpha_2=\frac{K_{a1}K_{a2}[H^+]}{D},\;\alpha_3=\frac{K_{a1}K_{a2}K_{a3}}{D} \]
Symbol legend
  • \(\alpha_i\): mole fraction of species i
  • \(c_i\): concentration of species i [mol/L]
  • \(C_T\): total concentration of all species [mol/L]
  • \([H^+]\): proton concentration [mol/L]
  • \(K_{a1},K_{a2},K_{a3}\): stepwise acid dissociation constants
  • \(\mathrm{p}K_{a1},\mathrm{p}K_{a2},\mathrm{p}K_{a3}\): negative decimal logarithms of \(K_a\)
  • \(D\): normalization denominator of distribution functions


Detailed examples
Example 1 (diprotic near pKa2):
When pH is close to pKa2, \(\alpha_1\) and \(\alpha_2\) are often comparable. The transition between \(\mathrm{HA^-}\) and \(\mathrm{A^{2-}}\) is most pronounced.
Example 2 (acidic region):
If pH is much lower than pKa1, the more protonated form dominates (e.g., H₂A or H₃A), relevant for extraction and separation conditions.
Example 3 (triprotic near neutral pH):
For systems like phosphate, an intermediate species can dominate around neutral pH, explaining characteristic buffering behavior.
Example 4 (absolute concentrations):
With \(C_T\), fractions convert directly to absolute concentrations through \(c_i=\alpha_iC_T\), enabling quantitative distribution assessment.
Deeper insight
Dominant-species window

Dominant species gives a practical criterion for selecting pH windows for reactions, complexation, and separation workflows.

Activities vs concentrations

At elevated ionic strength, activities deviate from concentrations. For high-accuracy work, activity corrections may shift effective pKa positions and distribution profiles.

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