Abstract
Methane C-H functionalization by radical pathways is often unselective and not desirable. Transition metal catalyzed C-H functionalization of methane to methanesulfonic acid (sulfonation) in sulfuric acid has generally been interpreted as resulting from a radical mechanism whereas functionalization to methyl bisulfate (oxygenation) has been proposed to occur by both radical and non-radical pathways. For Hg(II) and Au(III) catalysis, formation of either methanesulfonic acid or methyl bisulfate depends on whether 98% sulfuric acid or oleum (SO(3) added) is used. Here we report new experiments combined with density functional theory calculations that have revealed that selectivity is determined by non-radical pathways where a Hg(II)/Au(III)-methyl intermediate can undergo either an electrophilic substitution pathway (S(E)2) with SO(3) to form methanesulfonic acid or a nucleophilic substitution pathway (S(N)2) with bisulfate to form methyl bisulfate. The favored pathway is determined by the electrophilicity/reduction potential of the metal and the sulfuric acid to SO(3)/H(2)O equilibrium. Overall, this new selectivity model provides a straightforward understanding of product selectivity and does not require a functionalization mechanism involving radicals.