posted on 2023-11-28, 00:13authored byChuan-Pin Chen, Waad Alharbi, Thomas R. Cundari, Thomas W. Hamann, Milton R. Smith
We report an in-depth investigation
into the ammonia oxidation
mechanism by the catalyst [RuIII(tpy)(dmabpy)NH3]3+ ([Ru(NH3)]3+). Stoichiometric
reactions of [Ru(NH3)]3+ were carried out with
exogenous noncoordinating bases to trigger a proposed redox disproportionation
reaction, which was followed using variable-temperature NMR spectroscopy.
An intermediate species was identified as a dinitrogen-bridged complex
using 15N NMR and Raman spectroscopy on isotopically labeled
complexes. This intermediate is proposed to derive from coupling of
nitridyl species formed upon sequential redox disproportion reactions.
Acetonitrile displaces the dinitrogen bridge to yield free N2. DFT calculations support this lower-energy pathway versus that
previously reported for ammonia oxidation by the parent [RuIII(tpy)(bpy)NH3]3+ complex. These experimental
and computational results are consistent with the interpretation of
redox disproportionation involving sequential hydrogen atom transfer
reactions by an amide/aminyl intermediate, [Ru(NH2)−]+ ⇔ [Ru(NH2)•]+, formed upon deprotonation of the parent complex. Control
experiments employing a large excess of ammonia as a base indicate
this new proposed lower-energy pathway contributes to the oxidation
of ammonia to dinitrogen in conditions relevant to electrocatalysis.
In addition, analogous methylamine complexes, [Ru(NH2CH3)]2+/3+, were prepared to further test the proposed
mechanism. Treating [Ru(NH2CH3)]3+ with a base cleanly yields two products [Ru(NH2CH3)]2+ and [Ru(CN)]+ in an ∼3:1
ratio, fully consistent with the proposed cascade of hydrogen atom
transfer reactions by an intermediate.