Systematic Study of Oxygen Evolution Activity and Stability on La1–xSrxFeO3−δ Perovskite Electrocatalysts in Alkaline Media

She, Sixuan; Yu, Jie; Tang, Wanqi; Zhu, Yinlong; Chen, Yubo; Sunarso, Jaka; Zhou, Wei; Shao, Zongping

doi:10.1021/acsami.8b00682

Cited by 183 publications

(159 citation statements)

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“…Besides the active oxygen species, the metal oxidation state on the surface can also affect the catalytic performance. In this work, the OER activity of both cobalt‐doped catalysts (LFC82 and 3DOM‐LFC82) with cubic structure are better than their corresponding Fe‐based catalysts (LF and 3DOM‐LF) with orthorhombic structure, which is consistent with previous studies that the ideal cubic crystal structure can also contribute to the improved activity of OER . The 3DOM architecture and cubic crystal structure in 3DOM‐LFC82 brings about optimized iron oxidation state (e.g., Fe 4+ ), as characterized by XPS Fe 2p spectra (Figure S14, Supporting Information) and corresponding deconvolution results (Figure d and Table S4, Supporting Information) .…”

supporting

confidence: 90%

“…In particular, the iron‐rich perovskites always showed an obvious decrease in activity with time on operation. Refer to the poor activity issue, a few efforts have been devoted to looking for effective strategies (e.g., ion doping, deficiency tuning, and crystal‐structure design) to enhance the electrocatalytic activity . For example, She et al reported a systematic study of Sr‐doped La 1‐x Sr x FeO 3‐δ perovskites and found A‐site Sr‐doping could greatly improve OER activity of parent LaFeO 3 .…”

mentioning

confidence: 99%

“…Refer to the poor activity issue, a few efforts have been devoted to looking for effective strategies (e.g., ion doping, deficiency tuning, and crystal‐structure design) to enhance the electrocatalytic activity . For example, She et al reported a systematic study of Sr‐doped La 1‐x Sr x FeO 3‐δ perovskites and found A‐site Sr‐doping could greatly improve OER activity of parent LaFeO 3 . The OER activity of Fe‐based perovskite could also be improved by proper B‐site ion doping, e.g., Zr 4+ and Si 4+ .…”

mentioning

confidence: 99%

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Enabling High and Stable Electrocatalytic Activity of Iron‐Based Perovskite Oxides for Water Splitting by Combined Bulk Doping and Morphology Designing

Dai

Zhu

Zhong

et al. 2018

Adv Materials Inter

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COMMUNICATION (1 of 8)scale is mainly hindered by the large overpotential, originated largely from sluggish kinetics of anodic oxygen evolution reaction (OER) and cathodic hydrogen evolution reaction (HER). For commercial electrolyzers, a much higher operating potential (1.8-2.0 V) is always required than the theoretical value (1.23 V). [5] The iridium/ruthenium oxides (IrO 2 /RuO 2 ) and platinum (Pt) metal are recognized as the state-of-the-art catalysts toward anodic and cathodic reactions, respectively, [6] while their large-scale commercial application is restricted by high cost and resource scarcity. [7] Thus, it is necessary to rationally design high-performance, cost-effective, and abundant catalysts for water splitting. So far, diverse groups of materials including oxides, hydroxides, phosphides, chalcogenides, carbides, and nitrides, have been exploited as potential catalysts for water splitting with different benefits and drawbacks. [8,9] Perovskite oxides with the general formula of ABO 3 , where A is alkaline-and/or rare-earth metal and B is a transition metal (most of which is cobalt (Co), nickel (Ni), manganese (Mn), and iron (Fe)), have recently attracted considerable attention in the electrocatalysis field due to their high specific catalytic activity, compositional flexibility, and environmental friendliness. [10,11] From the point of practical applications, iron-based materials are more appealing in the family of perovskite considering that Fe metal is more earth-abundant and cheaper, and less toxic than Co and Ni metals. [12,13] However, Fe-based perovskites always show poor activity and unfavorable durability for OER. [14,15] In particular, the iron-rich perovskites always showed an obvious decrease in activity with time on operation. Refer to the poor activity issue, a few efforts have been devoted to looking for effective strategies (e.g., ion doping, deficiency tuning, and crystal-structure design) to enhance the electrocatalytic activity. [16][17][18][19][20] For example, She et al. reported a systematic study of Sr-doped La 1-x Sr x FeO 3-δ perovskites and found A-site Sr-doping could greatly improve OER activity of parent LaFeO 3 . [16] The OER activity of Fe-based perovskite could also be improved by proper B-site ion doping, e.g., Zr 4+ and Si 4+ . [17,18] Besides the ion doping, Zhu et al. also proposed a strategy for enhancing OER activity by introducing A-site deficiency in LaFeO 3 perovskite. [19] Yagi et al. prepared a quadruple perovskite CaCu 3 Fe 4 O 12 via a high-pressure method, which shows higher OER activity than the simple perovskites. [20] The catalysts for oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) are crucial for water splitting technology, and perovskite oxides have received tremendous attention as promising candidates due to the compositional flexibility and rich properties. Here, reported is the successful deployment of cost-effective iron-based perovskites into efficient water splitting catalysts with both high activity and stability by c...

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confidence: 99%

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Enabling High and Stable Electrocatalytic Activity of Iron‐Based Perovskite Oxides for Water Splitting by Combined Bulk Doping and Morphology Designing

Dai

Zhu

Zhong

et al. 2018

Adv Materials Inter

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“…This is further confirmed by soft X-ray adsorption spectro scopy (XAS) at the Co-L 3 and Fe-L 3 edges ( Figure S5, Supporting Information). Moreover, active SCFB-0.3 catalyst has the highest O 2 2− /O − species which was reported to be active for catalyzing OER, [18] thus contributing additional benefits for the improvement of the catalytic activity (Table S3, Supporting Information). However, the relative areas of OH − peak in O 1s core-level photoemission for these samples show a trend of monotonous decline as the proton-acceptor SB increased, and signals indicative of SB is playing a role in enhancing the deprotonation of OH − (Figure 3c; Table S2, Supporting Information).…”

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Realizing Ultrafast Oxygen Evolution by Introducing Proton Acceptor into Perovskites

She

Zhu

Chen

et al. 2019

Advanced Energy Materials

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The oxygen evolution reaction (OER) is of prime importance in multiple energy storage devices. Perovskite oxides involving lattice‐oxygen oxidation are generally regarded as highly active OER catalysts, but the deprotonation of surface‐bound intermediates limit the further activity improvement. Here, it is shown that this kinetic limitation can be removed by introducing Sr3B2O6 (SB) which activates a proton‐acceptor functionality to boost OER activity. As a proof‐of‐concept example, an experimental validation is conducted on the extraordinary OER performance of a Sr(Co0.8Fe0.2)0.7B0.3O3−δ (SCFB‐0.3) hybrid catalyst, made using Sr0.8Co0.8Fe0.2O3−δ as active component and SB as a proton acceptor. This smart hybrid exhibits an exceptionally ultrahigh OER activity with an extremely low overpotential of 340 mV in 0.1 m KOH and 240 mV in 1 m KOH required for 10 mA cm−2 which is the top‐level catalytic activity among metal oxides reported so far, while maintaining excellent durability. The correlation of pH and activity study reveals that this enhanced activity mainly originates from the improved interfacial proton transfer. Such a strategy further demonstrated to be universal, which can be applied to enhance the OER activity of other high covalent oxides with close O 2p‐band centers relative to Fermi energy.

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“…Over the recent years, a plethora of perovskite oxides have been reported as catalysts toward the electrocatalysis of the ORR, [27][28][29][30][31][32][33][34][35] OER, [36][37][38][39][40][41][42][43][44][45][46][47][48][49] HER, [50][51][52] and fuel oxidation. [53][54][55] In particular, many perovskites have been developed for precursors.…”

Section: Doi: 101002/smtd201800071mentioning

confidence: 99%

Recent Advances in Novel Nanostructuring Methods of Perovskite Electrocatalysts for Energy‐Related Applications

et al. 2018

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Perovskite oxides hold great promise as efficient electrocatalysts for various energy‐related applications owing to their low cost, flexible structure, and high intrinsic catalytic activity. However, conventional synthetic methods can only obtain perovskite catalysts with large particle sizes, small surface areas, and few morphological features, leading to limited catalytic activity and thus posing a major challenge toward real‐world applications. Reducing the size of bulk perovskites down to the nanosize represents an efficient way to improve the electrocatalytic performance. A comprehensive overview of recent progress in the nanostructuring of perovskites for catalyzing several key reactions in metal–air batteries, water splitting, and solid oxide fuel cells is provided. A range of synthetic protocols for making perovskite nanostructures are summarized, followed by an emphasis on how each method can be tailored to obtain high‐performing perovskite nanocatalysts. These recent advances highlight the enormous potential of nanosized perovskites for facilitating the electrocatalytic reactions. The remaining challenges and future directions are pointed out for the development of next‐generation perovskite‐based nanostructured catalysts.

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Systematic Study of Oxygen Evolution Activity and Stability on La_1–xSr_xFeO_3−δ Perovskite Electrocatalysts in Alkaline Media

Cited by 183 publications

References 44 publications

Enabling High and Stable Electrocatalytic Activity of Iron‐Based Perovskite Oxides for Water Splitting by Combined Bulk Doping and Morphology Designing

Enabling High and Stable Electrocatalytic Activity of Iron‐Based Perovskite Oxides for Water Splitting by Combined Bulk Doping and Morphology Designing

Realizing Ultrafast Oxygen Evolution by Introducing Proton Acceptor into Perovskites

Recent Advances in Novel Nanostructuring Methods of Perovskite Electrocatalysts for Energy‐Related Applications

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