Superacid

According to the classical definition superacid is an acid with an acidity greater than that of 100% pure sulfuric acid,^[1] which has a Hammett acidity function (H₀) of −12. According to the modern definition, superacid is a medium, in which the chemical potential of the proton is higher than in pure sulfuric acid.^[2] Commercially available superacids include trifluoromethanesulfonic acid (CF₃SO₃H), also known as triflic acid, and fluorosulfonic acid (FSO₃H), both of which are about a thousand times stronger (i.e. have more negative H₀ values) than sulfuric acid. The strongest superacids are prepared by the combination of two components, a strong Lewis acid and a strong Brønsted acid. The strongest known superacid is fluoroantimonic acid.

Unstable gas-phase heteroelement-hydride ions can be extremely acidic, e.g. the helium hydride ion. However, they are not considered as such because they exist only in extremely hot plasma not in the liquid state.

History

The term superacid was originally coined by James Bryant Conant in 1927 to describe acids that were stronger than conventional mineral acids.^[1] George A. Olah prepared the so-called magic acid, so-named for its ability to attack hydrocarbons, by mixing antimony pentafluoride (SbF₅) and fluorosulfonic acid (FSO₃H). The name was coined after a candle was placed in a sample of magic acid. The candle dissolved, showing the ability of the acid to protonate hydrocarbons, which under normal acidic conditions do not protonate to any extent.

It was shown that at 140 °C (284 °F), FSO₃H–SbF₅ will convert methane into the tertiary-butyl carbocation, a reaction that begins with the protonation of methane:^[3]

CH₄ + H⁺ → CH₅⁺

CH₅⁺ → CH₃⁺ + H₂

CH₃⁺ + 3 CH₄ → (CH₃)₃C⁺ + 3H₂

Superlatives and metaphors

Fluoroantimonic acid, the strongest acid in the system, is 2×10¹⁶ times stronger than 100% sulfuric acid,^[4] and can produce solutions with a H₀ down to –28.^[5] Fluoroantimonic acid is a combination of hydrofluoric acid and SbF₅. In this system, HF releases its proton (H⁺) concomitant with the binding of F⁻ by the antimony pentafluoride. The resulting anion (SbF₆⁻) is both a weak nucleophile and a weak base.

The proton from superacids has been popularly said to become "naked," accounting for the system's extreme acidity. In the physical sense, the acidic "proton" is never completely free (as an unbound proton) in the acid, but rather hops from anion to anion in superacids via the Grotthuss mechanism, just as happens to acidic "protons" in water.^[6] The extreme acidity of the acids is due to the ease with which this proton is transferred to substances that cannot normally be "protonated" (such as hydrocarbons), due to the very high stability of the conjugate-base anion (such as SbF₆⁻) after it donates the proton.

Applications

Common uses of superacids include providing an environment to create and maintain organic cations, which are useful as intermediate molecules in numerous reactions, such as those involving plastics and in the production and study of high-octane gasoline .^[7]

See also

• Superbase

References

1. Hall NF, Conant JB (1927). "A Study of Superacid Solutions". Journal of the American Chemical Society. 49 (12): 3062–70. doi:10.1021/ja01411a010.
2. Himmel D, Goll SK, Leito I, Krossing I (2010). "A Unified pH Scale for All Phases". Angew. Chem. Int. Ed. 49 (38): 6885–6888. doi:10.1002/anie.201000252.
3. George A. Olah, Schlosberg RH (1968). "Chemistry in Super Acids. I. Hydrogen Exchange and Polycondensation of Methane and Alkanes in FSO₃H–SbF₅ ("Magic Acid") Solution. Protonation of Alkanes and the Intermediacy of CH₅⁺ and Related Hydrocarbon Ions. The High Chemical Reactivity of "Paraffins" in Ionic Solution Reactions". Journal of the American Chemical Society. 90 (10): 2726–7. doi:10.1021/ja01012a066.
4. Olah, George A. (2005). "Crossing Conventional Boundaries in Half a Century of Research". Journal of Organic Chemistry. 70 (7): 2413–2429. doi:10.1021/jo040285o. PMID 15787527.
5. Herlem, Michel (1977). "Are reactions in superacid media due to protons or to powerful oxidising species such as SO₃ or SbF₅?". Pure & Applied Chemistry. 49: 107–113. doi:10.1351/pac197749010107.
6. [1] Computer modeling of proton-hopping in superacids.
7. Fluoroantimonic Acid