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Hammett acidity function

Measure of acidity used for extremely acidic solutions

Acids and bases
Acceptor number Acid Acid–base reaction Acid–base homeostasis Acid strength Acidity function Amphoterism Base Buffer solutions Dissociation constant Donor number Equilibrium chemistry Extraction Hammett acidity function pH Proton affinity Self-ionization of water Titration Lewis acid catalysis Frustrated Lewis pair Chiral Lewis acid ECW model
Acid types
Brønsted–Lowry Lewis Mineral Organic Oxide Strong Superacids Weak Solid
Base types
Brønsted–Lowry Lewis Organic Oxide Strong Superbases Non-nucleophilic Weak
v t e

The Hammett acidity function (H₀) is a measure of acidity that is used for very concentrated solutions of strong acids, including superacids. It was proposed by the physical organic chemist Louis Plack Hammett^[1][2] and is the best-known acidity function used to extend the measure of Brønsted–Lowry acidity beyond the dilute aqueous solutions for which the pH scale is useful.

In highly concentrated solutions, simple approximations such as the Henderson–Hasselbalch equation are no longer valid due to the variations of the activity coefficients. The Hammett acidity function is used in fields such as physical organic chemistry for the study of acid-catalyzed reactions, because some of these reactions use acids in very high concentrations, or even neat (pure).^[3]

Definition[edit]

The Hammett acidity function, H₀, can replace the pH in concentrated solutions. It is defined using an equation^[4][5][6] analogous to the Henderson–Hasselbalch equation:

${\displaystyle H_{0}={\mbox{p}}K_{{\ce {BH^+}}}+\log {\frac {{\ce {[$B]}}}{{\ce {[BH^+]}}}}}

where log(x) is the common logarithm of x, and pK_BH⁺ is −log(K) for the dissociation of BH⁺, which is the conjugate acid of a very weak base B, with a very negative pK_BH⁺. In this way, it is rather as if the pH scale has been extended to very negative values. Hammett originally used a series of anilines with electron-withdrawing groups for the bases.^[3]

Hammett also pointed out the equivalent form

${\displaystyle H_{0}=-\log \left(a_{{\ce {H^+}}}{\frac {\gamma _{{\ce {B}}}}{\gamma _{{\ce {BH^+}}}}}\right)}$

where a is the activity, and the γ are thermodynamic activity coefficients. In dilute aqueous solution (pH 0–14) the predominant acid species is H₃O⁺ and the activity coefficients are close to unity, so H₀ is approximately equal to the pH. However, beyond this pH range, the effective hydrogen-ion activity changes much more rapidly than the concentration.^[4] This is often due to changes in the nature of the acid species; for example in concentrated sulfuric acid, the predominant acid species ("H⁺") is not H₃O⁺ but rather H₃SO₄^{+[citation needed]}, which is a much stronger acid. The value H₀ = -12 for pure sulfuric acid must not be interpreted as pH = −12 (which would imply an impossibly high H₃O⁺ concentration of 10⁺¹² mol/L in ideal solution). Instead it means that the acid species present (H₃SO₄⁺) has a protonating ability equivalent to H₃O⁺ at a fictitious (ideal) concentration of 10¹² mol/L, as measured by its ability to protonate weak bases.

Although the Hammett acidity function is the best known acidity function, other acidity functions have been developed by authors such as Arnett, Cox, Katrizky, Yates, and Stevens.^[3]

Typical values[edit]

On this scale, pure H₂SO₄ (18.4 M) has a H₀ value of −12, and pyrosulfuric acid has H₀ ~ −15.^[7] Take note that the Hammett acidity function clearly avoids water in its equation. It is a generalization of the pH scale—in a dilute aqueous solution (where B is H₂O), pH is very nearly equal to H₀. By using a solvent-independent quantitative measure of acidity, the implications of the leveling effect are eliminated, and it becomes possible to directly compare the acidities of different substances (e.g. using pK_a, HF is weaker than HCl or H₂SO₄ in water but stronger than HCl in glacial acetic acid.^[8][9])

H₀ for some concentrated acids:^[10]

• Helonium: −63
• Fluoroantimonic acid (1990): −23 > H₀ > −28
• Magic acid (1974): −23
• Carborane superacids: H₀ < −18.0
• Fluorosulfuric acid (1944): −15.1
• Hydrogen fluoride: −15.1
• Trifluoromethanesulfonic acid (1940): −14.9
• Perchloric acid: −13
• Sulfurochloridic acid: −13.8; −12.78^[11]
• Sulfuric acid: −12.0

For mixtures (e.g., partly diluted acids in water), the acidity function depends on the composition of the mixture and has to be determined empirically. Graphs of H₀vsmole fraction can be found in the literature for many acids.^[3]

References[edit]