Selecting between two transition states by which water oxidation intermediates on an oxide surface decay
X. Chen, D. J. Aschaffenburg, T. Cuk

TL;DR
This study uncovers two parallel transition state pathways for water oxidation intermediates on an oxide surface, revealing how reaction conditions influence the decay mechanisms and providing insights for designing better catalysts.
Contribution
We experimentally identified and characterized two distinct transition state pathways for water oxidation intermediates on an oxide surface, linking them to specific surface sites and reaction conditions.
Findings
Two reaction-dependent decay pathways identified
Activation barriers of 0.4-0.5 eV measured
Reaction conditions influence pathway selection
Abstract
While catalytic mechanisms on electrode surfaces have been proposed for decades, the pathways by which the product's chemical bonds evolve from the initial charge-trapping intermediates have not been resolved in time. Here, we discover a reactive population of charge-trapping intermediates with states in the middle of a semiconductor's band-gap to reveal the dynamics of two parallel transition state pathways for their decay. Upon photo-triggering the water oxidation reaction from the n-SrTiO3 surface with band-gap, pulsed excitation, the intermediates' microsecond decay reflects transition state theory (TST) through: (1) two distinct and reaction dependent (pH, T, Ionic Strength, and H/D exchange) time constants, (2) a primary kinetic salt effect on each activation barrier and an H/D kinetic isotope effect on one, and (3) realistic activation barrier heights (0.4 - 0.5 eV) and TST…
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Taxonomy
TopicsElectronic and Structural Properties of Oxides · Semiconductor materials and devices · Electrochemical Analysis and Applications
