Atomically dispersed nonmagnetic electron traps improve oxygen reduction activity of perovskite oxides

Nonmagnetic hexavalent molybdenum atomically dispersed within oxide lattice steers the intrinsic oxygen reduction activity of catalytically active sites, and excludes the occurrence of lattice symmetry breaking and magnetic perturbation.

Complexity in strongly correlated oxides such as perovskite strictly dominates their performance for oxygen reduction reaction (ORR). Precise control of the physical correlations among spin, charge, orbital, and lattice degrees of freedom in these oxides can exercise considerable enhancement of ORR activity, but has until now remained elusive. Here, we show that nonmagnetic hexavalent molybdenum (Mo ⁶⁺) atomically dispersed within oxide lattice steers the intrinsic activity of catalytically active sites by entrapping extrinsic electrons at their 3d orbitals, without the occurrence of lattice symmetry breaking and magnetic perturbation. With double perovskite La ₂Co ²⁺Mn ⁴⁺O ₆ as a model catalyst, the atomic-scale electron trap generates additional high-spin, catalytically active Mn ³⁺(t32ge1g) sites and highly conductive Co ²⁺(e2g)–O–Mn ³⁺(e1g) double exchange channels, leading to five-fold improvement in ORR activity. First-principles calculations reveal a substantial increase of the spin density on Mn sites caused by electron trapping, and unambiguously confirm a more exothermic reaction pathway as well as a lower barrier of the rate-limiting surface hydroxide regeneration on Mo ₁/La ₂CoMnO ₆. We can also extend this strategy with atomic precision easily to other four oxide catalysts and achieve large enhancement in their ORR activities as anticipated, indicating its broad utility. This work embodies the theories of condensed matter physics in rational design of ORR catalysts, and may inspire further development of the control of electron correlation in strongly correlated electron systems.