Abstract
The direct conversion of methane to methanol would enable better utilization of abundant natural gas resources. In the presence of stoichiometric Pt(IV) oxidants, Pt(II) ions are capable of catalyzing this reaction in aqueous solutions at modest temperatures. Practical implementation of this chemistry requires a viable strategy for replacing or regenerating the expensive Pt(IV) oxidant. Herein, we establish an electrochemical strategy for continuous regeneration of the Pt(IV) oxidant to furnish overall electrochemical methane oxidation. We show that Cl-adsorbed Pt electrodes catalyze facile oxidation of Pt(II) to Pt(IV) at low overpotential without concomitant methanol oxidation. Exploiting this facile electrochemistry, we maintain the Pt(II/IV) ratio during Pt(II)-catalyzed methane oxidation via in situ monitoring of the solution potential coupled with dynamic modulation of the electric current. This approach leads to sustained methane oxidation catalysis with 70% selectivity for methanol.