Electrocatalytic Ammonia Oxidation with a Tailored Molecular Catalyst Heterogenized via Surface Host-Guest Complexation

Macrocyclic host molecules bound to electrode surfaces enable the complexation of catalytically active guests for molecular heterogeneous catalysis. We present a surface-anchored host-guest complex with the ability to electrochemically oxidize ammonia in both organic and aqueous solutions. With an adamantyl motif as the binding group on the backbone of the molecular catalyst [Ru(bpy-NMe2)(tpada)(Cl)](PF6) (<bold>1</bold>) (where bpy-NMe2 is 4,4 '-bis(dimethylamino)-2,2 '-bipyridyl and tpada is 4 '-(adamantan-1-yl)-2,2':6 ',2 ''-terpyridine), high binding constants with beta-cyclodextrin were observed in solution (in DMSO-d(6):D2O (7:3), K-11 = 492 +/- 21 M-1). The strong binding affinities were also transferred to a mesoporous ITO (mITO) surface functionalized with a phosphonated derivative of beta-cyclodextrin. The newly designed catalyst (<bold>1</bold>) was compared to the previously reported naphthyl-substituted catalyst [Ru(bpy-NMe2)(tpnp)(Cl)](PF6) (<bold>2</bold>) (where tpnp is 4 '-(naphthalene-2-yl)-2,2':6 ',2 ''-terpyridine) for its stability during catalysis. Despite the insulating nature of the adamantyl substituent serving as the binding group, the stronger binding of this unit to the host-functionalized electrode and the resulting shorter distance between the catalytic active center and the surface led to better performance and higher stability. Both guests are able to oxidize ammonia in both organic and aqueous solutions, and the host-anchored electrode can be refunctionalized multiple times (>3) following the loss of the catalytic activity, without a reduction in performance. Guest <bold>1</bold> exhibits significantly higher stability in comparison to guest <bold>2</bold> toward basic conditions, which often constitutes a challenge for anchored molecular systems. Ammonia oxidation in water led to the selective formation of NO3- with Faradaic efficiencies of up to 100%.