Deciphering the precise physical mechanism of interaction between an adsorbed species and a reactive site in heterogeneous catalysis is crucial for predictive design of highly efficient catalysts. Here, using first-principles calculations we identify that the two-dimensional ferromagnetic metal organic framework of Mn2C18H12 can serve as a highly efficient single-atom catalyst for spin-triplet O2 activation and CO oxidation. The underlying mechanism is via "concerted charge-spin catalysis", involving a delicate synergetic process of charge transfer, provided by the hosting Mn atom, and spin selection, preserved through active participation of its nearest neighboring Mn atoms for the crucial step of O2 activation. The synergetic mechanism is further found to be broadly applicable in O2 adsorption on magnetic X2C18H12 (X = Mn, Fe, Co, and Ni) with a well-defined linear scaling dependence between the chemical activity and spin excitation energy. The present findings provide new insights into chemical reactions wherein spin selection plays a vital role.
Keywords: Charge transfer; First-principles calculations; Metal−organic-framework; Single-atom catalyst; Spin selection.