Perovskite Oxide Based Electrodes for the Oxygen Reduction and Evolution Reactions: The Underlying Mechanism

Beall, Casey E.; Fabbri, Emiliana; Schmidt, Thomas J.

doi:10.1021/acscatal.0c04473

“…This suggests that the lattice oxygen evolution reaction (LOER), besides the conventional OER mechanism, takes place on the surface of the PBCO samples [4, 7c–f] . The participation of perovskite lattice oxygen to the OER generally leads to the catalyst surface reconstruction, specifically to the formation of a superficial oxyhydroxide layer [5a, 6, 7a,b,e, 32] . Furthermore, the LOER and the formation of the oxyhydroxide layer are also accompanied by cation dissolution as expressed in Equation 1.

true 2 normalA normalB O_{3 - δ} + 2 normalO {normalH}^{-} \leftrightarrow 2 normalB normalO ((), O, H) + {2 normalA}_{normala normalq}^{2 +} + O_{2} (() 2 - δ) + 6 {normale}^{-}

…”

Section: Resultsmentioning

confidence: 99%

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Marelli

¹

,

Gàzquez

²

,

Poghosyan

³

et al. 2021

Self Cite

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The role of the perovskite lattice oxygen in the oxygen evolution reaction (OER) is systematically studied in the PrBaCo2O5+δ family. The reduced number of physical/chemical variables combined with in‐depth characterizations such as neutron dif‐fraction, O K‐edge X‐ray absorption spectroscopy (XAS), electron energy loss spectroscopy (EELS), magnetization and scanning transmission electron microscopy (STEM) studies, helps investigating the complex correlation between OER activity and a single perovskite property, such as the oxygen content. Larger amount of oxygen vacancies appears to facilitate the OER, possibly contributing to the mechanism involving the oxidation of lattice oxygen, i.e., the lattice oxygen evolution reaction (LOER). Furthermore, not only the number of vacancies but also their local arrangement in the perovskite lattice influences the OER activity, with a clear drop for the more stable, ordered stoichiometry.

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“…As alternatives, crystalline, nonstoichiometric, mixed ionic–electronic conducting oxides belonging to the perovskite family of the general form A n +1 B n O 3 n +1 ( n = 1, 2, 3, ... ∞; A and B represent alkaline-earth-/rare-earth-metal and transition-metal (TM) cations, respectively) have been explored. 18 , 19 , 24 , 32 − 35 These oxides can accommodate >90% of the metals in the periodic table in their structure, giving rise to a significant number of opportunities to tune their catalytic performance. 36 For instance, variations in the A-site composition can be used to tune the electronic structure and catalytic properties of TM cations in these oxides.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Surface Reconstruction Unifies the Electrocatalytic Oxygen Evolution Performance of Nonstoichiometric Mixed Metal Oxides

Samira

¹

,

Hong

²

,

Camayang

³

et al. 2021

JACS Au

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Compositionally versatile, nonstoichiometric, mixed ionic–electronic conducting metal oxides of the form A n +1 B n O 3 n +1 ( n = 1 → ∞; A = rare-earth-/alkaline-earth-metal cation; B = transition-metal (TM) cation) remain a highly attractive class of electrocatalysts for catalyzing the energy-intensive oxygen evolution reaction (OER). The current design strategies for describing their OER activities are largely derived assuming a static, unchanged view of their surfaces, despite reports of dynamic structural changes to 3d TM-based perovskites during OER. Herein, through variations in the A- and B-site compositions of A n +1 B n O 3 n +1 oxides ( n = 1 (A 2 BO 4 ) or n = ∞ (ABO 3 ); A = La, Sr, Ca; B = Mn, Fe, Co, Ni), we show that, in the absence of electrolyte impurities, surface restructuring is universally the source of high OER activity in these oxides and is dependent on the initial oxide composition. Oxide surface restructuring is induced by irreversible A-site cation dissolution, resulting in in situ formation of a TM oxyhydroxide shell on top of the parent oxide core that serves as the active surface for OER. The rate of surface restructuring is found to depend on (i) composition of A-site cations, with alkaline-earth-metal cations dominating lanthanide cation dissolution, (ii) oxide crystal phase, with n = 1 A 2 BO 4 oxides exhibiting higher rates of A-site dissolution in comparison to n = ∞ ABO 3 perovskites, (iii) lattice strain in the oxide induced by mixed rare-earth- and alkaline-earth-metal cations in the A-site, and (iv) oxide reducibility. Among the in situ generated 3d TM oxyhydroxide structures from A n +1 B n O 3 n +1 oxides, Co-based structures are characterized by superior OER activity and stability, even in comparison to as-synthesized Co-oxyhydroxide, pointing to the generation of high active surface area structures through oxide restructuring. These insights are critical toward the development of revised design criteria to include surface dynamics for effectively describing the OER activity of nonstoichiometric mixed-metal oxides.

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“…The formation of a superficial oxyhydroxide layer does not necessarily leads to catalyst instability under OER conditions. Indeed, recent results suggest that for some OER catalysts a dynamic equilibrium between cation dissolution and re‐deposition can be reached, leading to a co‐existence of the perovskite structure and the superficial oxyhydroxide phase [5a, 6, 7a,b,e, 32] . Furthermore, the self‐assembled oxyhydroxide layer can itself undergo LOER and metal cation dissolution, as described in ref.…”

Section: Resultsmentioning

confidence: 90%

“…This suggests that the lattice oxygen evolution reaction (LOER), besides the conventional OER mechanism, takes place on the surface of the PBCO samples [4, 7c–f] . The participation of perovskite lattice oxygen to the OER generally leads to the catalyst surface reconstruction, specifically to the formation of a superficial oxyhydroxide layer [5a, 6, 7a,b,e, 32] . Furthermore, the LOER and the formation of the oxyhydroxide layer are also accompanied by cation dissolution as expressed in Equation 1.

true 2 normalA normalB O_{3 - δ} + 2 normalO {normalH}^{-} \leftrightarrow 2 normalB normalO ((), O, H) + {2 normalA}_{normala normalq}^{2 +} + O_{2} (() 2 - δ) + 6 {normale}^{-}

…”

Section: Resultsmentioning

confidence: 99%

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Marelli

¹

,

Gàzquez

²

,

Poghosyan

³

et al. 2021

Self Cite

View full text Add to dashboard Cite

The role of the perovskite lattice oxygen in the oxygen evolution reaction (OER) is systematically studied in the PrBaCo2O5+δ family. The reduced number of physical/chemical variables combined with in‐depth characterizations such as neutron dif‐fraction, O K‐edge X‐ray absorption spectroscopy (XAS), electron energy loss spectroscopy (EELS), magnetization and scanning transmission electron microscopy (STEM) studies, helps investigating the complex correlation between OER activity and a single perovskite property, such as the oxygen content. Larger amount of oxygen vacancies appears to facilitate the OER, possibly contributing to the mechanism involving the oxidation of lattice oxygen, i.e., the lattice oxygen evolution reaction (LOER). Furthermore, not only the number of vacancies but also their local arrangement in the perovskite lattice influences the OER activity, with a clear drop for the more stable, ordered stoichiometry.

show abstract

Perovskite Oxide Based Electrodes for the Oxygen Reduction and Evolution Reactions: The Underlying Mechanism

Cited by 167 publications

References 157 publications

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Dynamic Surface Reconstruction Unifies the Electrocatalytic Oxygen Evolution Performance of Nonstoichiometric Mixed Metal Oxides

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

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Perovskite Oxide Based Electrodes for the Oxygen Reduction and Evolution Reactions: The Underlying Mechanism

Cited by 167 publications

References 157 publications

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo2O5+δ

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo2O5+δ

Dynamic Surface Reconstruction Unifies the Electrocatalytic Oxygen Evolution Performance of Nonstoichiometric Mixed Metal Oxides

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo2O5+δ

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Product

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Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ

Correlation between Oxygen Vacancies and Oxygen Evolution Reaction Activity for a Model Electrode: PrBaCo₂O_5+δ