Electrocatalytic Hydrogen
Evolution at Full Atomic
Utilization over ITO-Supported Sub-nano-Ptn Clusters: High, Size-Dependent Activity Controlled by Fluxional
Pt Hydride Species
posted on 2023-03-03, 16:35authored bySimran Kumari, Tsugunosuke Masubuchi, Henry S. White, Anastassia Alexandrova, Scott L. Anderson, Philippe Sautet
A combination of density functional theory (DFT) and
experiments
with atomically size-selected Ptn clusters
deposited on indium-tin oxide (ITO) electrodes was used to examine
the effects of applied potential and Ptn size on the electrocatalytic activity of Ptn (n = 1, 4, 7, and 8) for the hydrogen evolution
reaction (HER). Activity is found to be negligible for isolated Pt
atoms on ITO, increasing rapidly with Ptn size such that Pt7/ITO and Pt8/ITO have roughly
double the activity per Pt atom compared to atoms in the surface layer
of polycrystalline Pt. Both the DFT and experiment find that hydrogen
under-potential deposition (Hupd) results in Ptn/ITO (n = 4, 7, and 8) adsorbing
∼2H atoms/Pt atom at the HER threshold potential, equal to
ca. double the Hupd observed for Pt bulk or nanoparticles.
The cluster catalysts under electrocatalytic conditions are hence
best described as a Pt hydride compound, significantly departing from
a metallic Pt cluster. The exception is Pt1/ITO, where
H adsorption at the HER threshold potential is energetically unfavorable.
The theory combines global optimization with grand canonical approaches
for the influence of potential, uncovering the fact that several metastable
structures contribute to the HER, changing with the applied potential.
It is hence critical to include reactions of the ensemble of energetically
accessible PtnHx/ITO structures to correctly predict the activity vs Ptn size and applied potential. For the small
clusters, spillover of Hads from the clusters to the ITO
support is significant, resulting in a competing channel for loss
of Hads, particularly at slow potential scan rates.