Cooperative Effects Drive Water Oxidation Catalysis in Cobalt Electrocatalysts through the Destabilization of Intermediates.
Benjamin MossKatrine Louise SvaneDavid Nieto-CastroReshma R RaoSoren B ScottCindy TsengMichael SachsAnuj PennathurCaiwu LiangLouise I OldhamEva MazzoliniLole JuradoGopinathan SankarStephen ParryVerónica CelorrioJahan M DawlatyJan RossmeislJose Ramon Galan-MascarosIfan E L StephensJames R DurrantPublished in: Journal of the American Chemical Society (2024)
A barrier to understanding the factors driving catalysis in the oxygen evolution reaction (OER) is understanding multiple overlapping redox transitions in the OER catalysts. The complexity of these transitions obscure the relationship between the coverage of adsorbates and OER kinetics, leading to an experimental challenge in measuring activity descriptors, such as binding energies, as well as adsorbate interactions, which may destabilize intermediates and modulate their binding energies. Herein, we utilize a newly designed optical spectroelectrochemistry system to measure these phenomena in order to contrast the behavior of two electrocatalysts, cobalt oxyhydroxide (CoOOH) and cobalt-iron hexacyanoferrate (cobalt-iron Prussian blue, CoFe-PB). Three distinct optical spectra are observed in each catalyst, corresponding to three separate redox transitions, the last of which we show to be active for the OER using time-resolved spectroscopy and electrochemical mass spectroscopy. By combining predictions from density functional theory with parameters obtained from electroadsorption isotherms, we demonstrate that a destabilization of catalytic intermediates occurs with increasing coverage. In CoOOH, a strong (∼0.34 eV/monolayer) destabilization of a strongly bound catalytic intermediate is observed, leading to a potential offset between the accumulation of the intermediate and measurable O 2 evolution. We contrast these data to CoFe-PB, where catalytic intermediate generation and O 2 evolution onset coincide due to weaker binding and destabilization (∼0.19 eV/monolayer). By considering a correlation between activation energy and binding strength, we suggest that such adsorbate driven destabilization may account for a significant fraction of the observed OER catalytic activity in both materials. Finally, we disentangle the effects of adsorbate interactions on state coverages and kinetics to show how adsorbate interactions determine the observed Tafel slopes. Crucially, the case of CoFe-PB shows that, even where interactions are weaker, adsorption remains non-Nernstian, which strongly influences the observed Tafel slope.
Keyphrases
- density functional theory
- aqueous solution
- reduced graphene oxide
- metal organic framework
- high resolution
- heavy metals
- molecular dynamics
- gold nanoparticles
- dna binding
- binding protein
- electron transfer
- highly efficient
- single molecule
- risk assessment
- carbon nanotubes
- affordable care act
- magnetic resonance imaging
- crystal structure
- hydrogen peroxide
- mass spectrometry
- big data
- transcription factor