Theory, Substantiation, And Properties Of Novel Reversible Electrocatalysts For Oxygen Electrode Reactions

Hypo-d(f)-oxides of transition elements (d = 5) usually feature decisive and highly pronounced effects of spontaneous adsorptive dissociation of water molecules, as the main and initial thermodynamic precondition state for the reversible latent storage and spillover properties of primary oxides (Pt-OH, Au-OH), otherwise indispensable ingredients in electrocatalysis for the oxygen electrode reactions. The higher the altervalent number (or capacity) of the former, and when mostly further advanced for the proper mixed valence hypo-d(f)-oxide supports, the higher the overall (electro)catalytic yields primarily for cathodic oxygen reduction (ORR) and its anodic evolution (OER). In fact, cyclic voltammetry revealed the interrelated redox properties of the primary (Pt-OH) and surface (Pt=O) oxides between the cathodic hydrogen and anodic oxygen evolving limits, though the former has already been for longer known as the intermediate state from hydrogen oxidation in heterogeneous Doeberriner reaction upon Pt catalyst, and as being water molecules self-catalyzed (Ertel). Such interfering interrelated and autocatalytic species substantially define electrocatalytic properties of plain (Pt) or noninteractive supported noble metals (Pt/C), along the potential axis, and within some range even make them highly polarizable. Meanwhile, the latter can be continuously and successfully electrocatalytically depolarized and maintained reactivated. Such spontaneously renewable activation and maintenance of the reversible electrocatalytic state for the oxygen electrode reactions all along such cyclic voltammograms is the main Sir William Grove target challenge of the present study. In such a respect, continuously and spontaneously renewable adsorptive water molecule dissociation effectively means and enables the latent storage and electrocatalytic spillover properties of the primary oxide(s) for the reversible oxygen electrode (ROE) behavior, and these have been identified and substantiated, back and forth, all along the potential axis between hydrogen and oxygen evolving limits. Such advanced electrocatalytic properties imply selective grafting of interactive (SMSI, strong metalsupport interaction) nanostructured hyper-d-Pt (Au, RuPt) clusters upon individual and/or preferably composite mixed valence hypo-d-(f)-oxide supports. The latter then feature the extra high stability, pronounced electronic conductivity, and many other d-electronic-based metal properties mostly arising and being established upon the hypo-hyper-d-d-(f)-interelectronic bonding effect, along with and based upon spontaneous dissociative water molecule adsorption upon exposed oxide support surfaces, thereby yielding renewable primary oxide latent storage by simple continuous water vapor supply and imposed characteristic membrane type hydroxide ion surface migration. Migrating hydroxide, as individual species, under imposed polarization transfers its prevailing part of electron to the metallic electrocatalyst, hence resulting as the Pt-OH (Au-OH) dipole, and by the surface repulsion obeys reversible spillover distribution and imposes the electrocatalytic ROE properties all over the catalyst surface and DL pseudocapacitance charging and discharging, as well.The strong adsorptive surface oxide (Pt-O -> 1) deposition out of the primary oxide (Pt-OH -> 0) irreversible disproportionation thereby imposes unusually high reaction polarization of Pt, Au, Pd, and all other noble and transition d-metals within a very broad (600 mV, and even broader) potential range and, thereby, in general, mostly pronounced polarizable noncatalytic properties for oxygen electrode (ORR, OER) reactions. Thus, the strong interactive and selective hypohyper-dd-interelectronic grafting bonding of nanostructured individual (Pt) or prevailing hyper-d-intermetallic phase (MoPt3; HfPd3) cluster catalysts on altervalent and mixed-valence hypo-d(f)-oxide supports, as substantially and typically based upon the metallic d-d- or d-f-interelectronic bonding strengths and SMSI features, provide and keep just inferred basically all (inter)metallic properties of composite electrocatalysts, the primary oxide latent storage, and enhanced spillover and thereby enable approaching their reversible (electro)catalytic properties and optimization for the ROE. The reversibly revertible alterpolar bronze behaves (Pt/HxNbO5 <-> Pt/Nb(OH)(5), x approximate to 0.3) as the thermodynamic equilibrium alterpolar state, and thereby substantially advanced electrocatalytic properties of these composite interactive electrocatalysts for both oxygen (ORR, OER) and hydrogen (HOR, HER) electrode reactions, consequently, have been inferred as spontaneously altering and strong spillover features, in particular unique and superior for the revertible (PEMFC versus WE (water electrolysis)) cells.