Theoretical Investigation of Catalytic Water Splitting by the Arene-Anchored Actinide Complexes.

Actinide complexes, which could enable the electrocatalytic H 2 O reduction, are not well documented because of the fact that actinide-containing catalysts are precluded by extremely stable actinyl species. Herein, by using relativistic density functional theory calculations, the arene-anchored trivalent actinide complexes ( Me,Me ArO) 3 Ar An (marked as [AnL]) with desirable electron transport between metal and ligand arene are investigated for H 2 production. The metal center is changed from Ac to Pu. Electron-spin density calculations reveal a two-electron oxidative process (involving high-valent intermediates) for complexes [AnL] (An = P-Pu) along the catalytic pathway. The electrons are provided by both the actinide metal and the arene ring of ligand. This is comparable to the previously reported uranium catalyst ( Ad,Me ArO) 3 mes U (Ad = adamantine and mes = mesitylene). From the thermodynamic and kinetic perspectives, [PaL] offers appreciably lower reaction energies for the overall catalytic cycle than other actinide complexes. Thus, the protactinium complex tends to be the most reactive for H 2 O reduction to produce H 2 and has the advantage of its experimental accessibility.