Henderson–Hasselbalch equation

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In chemistry, the Henderson–Hasselbalch equation describes the derivation of pH as a measure of acidity (using pKa, the acid dissociation constant) in biological and chemical systems. The equation is also useful for estimating the pH of a buffer solution and finding the equilibrium pH in acid-base reactions (it is widely used to calculate the isoelectric point of proteins).

Two equivalent forms of the equation are

<math>\textrm{pH} = \textrm{pK}_{a}+ \log \frac{[\textrm{A}^-]}{[\textrm{HA}]}</math>

and

<math>\textrm{pH} = \textrm{pK}_{a}+\log \left ( \frac{[\textrm{conjugate base}]}{[\textrm{acid}]} \right ).</math>


Here, <math>\textrm{pK}_{a}</math> is <math>-\log (K_{a})</math> where <math>K_{a}</math> is the acid dissociation constant, that is:

<math>\textrm{pK}_{a} = - \log(K_{a}) = - \log \left ( \frac{[\mbox{H}_{3}\mbox{O}^+][\mbox{A}^-]}{[\mbox{HA}]} \right )</math> for the non-specific Brønsted acid-base reaction: <math>\mbox{HA} + \mbox{H}_{2}\mbox{O} \rightleftharpoons \mbox{A}^- + \mbox{H}_{3}\mbox{O}^+</math>

In these equations, <math>\mbox{A}^-</math> denotes the ionic form of the relevant acid. Bracketed quantities such as [base] and [acid] denote the molar concentration of the quantity enclosed.

In analogy to the above equations, the following equation is valid:

<math>\textrm{pOH} = \textrm{pK}_{b}+ \log \left ( \frac{[\textrm{BH}^+]}{[\textrm{B}]} \right )</math>

Where BH+ denotes the conjugate acid of the corresponding base B.

Derivation

The Henderson–Hasselbalch equation is derived from the acid dissociation constant equation by the following steps:

<math>K_\textrm{a} = \frac{[\textrm{H}^+][\textrm{A}^-]} {[\textrm{HA}]}</math>
<math>\log_{10}K_\textrm{a} = \log_{10} \left ( \frac{[\textrm{H}^+][\textrm{A}^-]}{[\textrm{HA}]} \right )</math>
<math>\log_{10}K_\textrm{a} = \log_{10}[\textrm{H}^+] + \log_{10} \left ( \frac{[\textrm{A}^-]}{[\textrm{HA}]} \right )</math>
<math>-\textrm{p}K_\textrm{a} = -\textrm{pH} + \log_{10} \left ( \frac{[\textrm{A}^-]}{[\textrm{HA}]} \right )</math>
<math>\textrm{pH} = \textrm{p}K_\textrm{a} + \log_{10} \left ( \frac{[\textrm{A}^-]}{[\textrm{HA}]} \right )</math>

The ratio <math>[A^-]/[HA]</math> is unitless, and as such, other ratios with other units may be used. For example, the mole ratio of the components, <math>n_{A^-}/n_{HA}</math> or the fractional concentrations <math>\alpha_{A^-}/\alpha_{HA}</math> where <math>\alpha_{A^-}+\alpha_{HA}=1</math> will yield the same answer. Sometimes these other units are more convenient to use.

History

Lawrence Joseph Henderson wrote an equation, in 1908, describing the use of carbonic acid as a buffer solution. Karl Albert Hasselbalch later re-expressed that formula in logarithmic terms, resulting in the Henderson–Hasselbalch equation [1]. Hasselbalch was using the formula to study metabolic acidosis.

Limitations

There are some significant approximations implicit in the Henderson–Hasselbalch equation. The most significant is the assumption that the concentration of the acid and its conjugate base at equilibrium will remain the same as the formal concentration. This neglects the dissociation of the acid and the hydrolysis of the base. The dissociation of water itself is neglected as well. These approximations will fail when dealing with relatively strong acids or bases (pKa more than a couple units away from 7), dilute or very concentrated solutions (less than 1 mM or greater than 1M), or heavily skewed acid/base ratios (more than 100 to 1). Also, the equation does not take into effect the dilution factor of the acid and conjugate base in water. If the proportion of acid to base is 1, then the pH of the solution will be different if the amount of water changes from 1mL to 1L.

See also

External links

References

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