Regulation of Perovskite Surface Stability on the Electrocatalysis of Oxygen Evolution Reaction

Zhao, Jiawei; Shi, Zi-Xiao; Li, Chengfei; Ren, Qian; Li, Gao‐Ren

doi:10.1021/acsmaterialslett.1c00018

Cited by 67 publications

(63 citation statements)

References 127 publications

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“…According to the current research progress, the alkaline‐earth metals are basically introduced into NNTM‐based oxides to modify their OER and/or HER activity. [ 142–167 ] Furthermore, the incorporation of alkaline‐earth metals mainly leads a fundamental role in the following four aspects. [ 145–165 ] i) Tuning the alkaline‐earth metal species in certain oxides can create lattice defects, which dictates a high conductivity and optimized free adsorption energy toward oxygen intermediates; ii) the alkaline‐earth metal species can gradually leach from the catalysts during catalysis, which will in situ leave pores in the phase reconstructed NNTM‐based (oxy)hydroxides catalysts, conducing to the exposure of active sites; iii) they mediate the formation of NNTM‐species with high oxidation state, thus resulting in the improvement of catalytic activity; and iv) the incorporation of some alkaline‐earth metal species into NNTM‐based phase can alter the morphology during synthesis, such as nanosheet, which is beneficial for the accessibility of reactants to surficial NNTM sites during catalysis.…”

Section: Merits Of S‐ P‐ and F‐block Metals In Water Electrolysismentioning

confidence: 99%

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

et al. 2022

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Basic Understanding of (Pre)catalysts toward Water Electrolysis Catalytic Mechanism of HER and OERWater splitting contains two half-reactions, HER and OER, and they present different reaction pathways in acidic versus alkaline media (Table 1). [76,77] The HER is composed of Volmer/ Heyrovsky or Volmer/Tafel steps as shown in Figure 2A. According to the reaction pathways, four intermediate steps including water adsorption, water dissociation, OH-adsorption, and hydrogen binding are involved in the alkaline HER process. Water adsorption is the first step of hydrogen evolution

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Section: Merits Of S‐ P‐ and F‐block Metals In Water Electrolysismentioning

confidence: 99%

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

et al. 2022

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“…[ 25 ] As illustrated in Figure 1 a,b , highly acidic electrolytes cause oxidative corrosion and dissolution of components, thereby inducing the loss of surface active centers and surface reconstruction during water electrolysis even for some robust compounds. [ 32 ] In general, complex interactions between active centers and intermediates/electrolytes under strong electric fields lead to surface reconstruction and thus activity decay. More importantly, such interactions exist in many cases, making the phenomena inevitable.…”

Section: Fundamental Principles For Shpmentioning

confidence: 99%

“…Either way, a bias higher than 1.23 eV is usually needed to overcome these thermodynamic hindrance and to initiate the OER, leading to an electron deficient state of the electrode/electrocatalyst and other types of surface reconstruction, e.g., components leaching and phase transformation even for highly stable perovskite catalysts. [32] Figure 1. a) Metal dissolution profile in relation to applied potential for Co/Co 2 P, Ni/Ni 5 P 4 , Mo/MoS 2 , and WC/W.…”

Section: Fundamental Principles For Shpmentioning

confidence: 99%

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Strategies for Electrochemically Sustainable H₂ Production in Acid

Hou

Quan

et al. 2022

Advanced Science

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Acidified water electrolysis with fast kinetics is widely regarded as a promising option for producing H 2 . The main challenge of this technique is the difficulty in realizing sustainable H 2 production (SHP) because of the poor stability of most electrode catalysts, especially on the anode side, under strongly acidic and highly polarized electrochemical environments, which leads to surface corrosion and performance degradation. Research efforts focused on tuning the atomic/nano structures of catalysts have been made to address this stability issue, with only limited effectiveness because of inevitable catalyst degradation. A systems approach considering reaction types and system configurations/operations may provide innovative viewpoints and strategies for SHP, although these aspects have been overlooked thus far. This review provides an overview of acidified water electrolysis for systematic investigations of these aspects to achieve SHP. First, the fundamental principles of SHP are discussed. Then, recent advances on design of stable electrode materials are examined, and several new strategies for SHP are proposed, including fabrication of symmetrical heterogeneous electrolysis system and fluid homogeneous electrolysis system, as well as decoupling/hybrid-governed sustainability. Finally, remaining challenges and corresponding opportunities are outlined to stimulate endeavors toward the development of advanced acidified water electrolysis techniques for SHP.

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“…The mechanism beneath high catalytic performance is related to lattice oxygen evolution reaction (LOER), which is characteristic of complex metal oxides (including perovskites). In light of recent studies [ 11 , 12 ], LOER is now seen as a fundamental process resulting in surface reconstruction towards highly active transition metal (oxy)hydroxides due to shallow perovskite A-site dissolution and B-site cation dissolution/re-deposition [ 13 , 14 , 15 , 16 ].…”

mentioning

confidence: 99%

Enhancement of Catalytic Activity and Stability of La0.6Ca0.4Fe0.7Ni0.3O2.9 Perovskite with ppm Concentration of Fe in the Electrolyte for the Oxygen Evolution Reaction

2021

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The catalytic activity and stability of an iron-nickel based oxygen-deficient perovskite for the oxygen evolution reaction (OER) are drastically improved with the ppm additive of Fe ions to the alkaline electrolyte. The enhancement is attributed to a 1–2 nm restructured Ni0.5Fe0.5Ox(OH)2-x (oxy)hydroxide layer, as demonstrated with scanning transmission electron microscopy. La0.6Ca0.4Fe0.7Ni0.3O2.9 shows almost a four-fold increase in OER activity after Fe addition relative to the as-prepared pristine electrolyte, which demonstrates the low Tafel slope of 44 ± 2.4 mV dec−1 and the superior intrinsic activity of 706 ± 71 A g−1oxide at 1.61 V vs. RHE.

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Regulation of Perovskite Surface Stability on the Electrocatalysis of Oxygen Evolution Reaction

Cited by 67 publications

References 127 publications

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

Strategies for Electrochemically Sustainable H₂ Production in Acid

Enhancement of Catalytic Activity and Stability of La0.6Ca0.4Fe0.7Ni0.3O2.9 Perovskite with ppm Concentration of Fe in the Electrolyte for the Oxygen Evolution Reaction

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Regulation of Perovskite Surface Stability on the Electrocatalysis of Oxygen Evolution Reaction

Cited by 67 publications

References 127 publications

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

Strategies for Electrochemically Sustainable H2 Production in Acid

Enhancement of Catalytic Activity and Stability of La0.6Ca0.4Fe0.7Ni0.3O2.9 Perovskite with ppm Concentration of Fe in the Electrolyte for the Oxygen Evolution Reaction

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Strategies for Electrochemically Sustainable H₂ Production in Acid