Identification of Highly Active Fe Sites in (Ni,Fe)OOH for Electrocatalytic Water Splitting

Friebel, Daniel; Louie, Mary W.; Bajdich, Michal; Sanwald, Kai E.; Cai, Yun; Wise, Anna M.; Cheng, Mu‐Jeng; Sokaras, Dimosthenis; Weng, Tsu Chien; Alonso-Mori, Roberto; Davis, Ryan C.; Bargar, John R.; Nørskov, Jens K.; Nilsson, Anders; Bell, Alexis T.

doi:10.1021/ja511559d

Cited by 2,101 publications

(2,482 citation statements)

References 73 publications

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“…Similarly, a volcano plot is reported, for example, among the perovskite‐structured oxides, which is correlated with the e g electron 134. Among the oxides composed of earth‐abundant materials, nickel–iron (oxy)hydroxide has been recently reconfirmed as a promising electrode in alkaline media 135, 136, 137, 138. In 2016, superior OER performance was revealed for the Ni–Co–W mixed oxyhydroxide, which requires an overpotential of only 191 mV to reach 10 mA cm −2 in 1.0 mol L −1 NaOH,139 and for Au‐supported NiCeO x , which reaches 10 mA cm −2 at an overpotential of 271 mV in 1.0 mol L −1 NaOH 140…”

Section: Oxygen Evolution Reaction (Oer)mentioning

confidence: 87%

Towards Versatile and Sustainable Hydrogen Production through Electrocatalytic Water Splitting: Electrolyte Engineering

2017

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Recent advances in power generation from renewable resources necessitate conversion of electricity to chemicals and fuels in an efficient manner. Electrocatalytic water splitting is one of the most powerful and widespread technologies. The development of highly efficient, inexpensive, flexible, and versatile water electrolysis devices is desired. This review discusses the significance and impact of the electrolyte on electrocatalytic performance. Depending on the circumstances under which the water splitting reaction is conducted, the required solution conditions, such as the identity and molarity of ions, may significantly differ. Quantitative understanding of such electrolyte properties on electrolysis performance is effective to facilitate the development of efficient electrocatalytic systems. The electrolyte can directly participate in reaction schemes (kinetics), affect electrode stability, and/or indirectly impact the performance by influencing the concentration overpotential (mass transport). This review aims to guide fine‐tuning of the electrolyte properties, or electrolyte engineering, for (photo)electrochemical water splitting reactions.

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Section: Oxygen Evolution Reaction (Oer)mentioning

confidence: 87%

Towards Versatile and Sustainable Hydrogen Production through Electrocatalytic Water Splitting: Electrolyte Engineering

2017

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“…The element Fe is proved to be effective for enhancing the OER activities of (oxy)hydroxides due to the enhanced structure disorder and conductivity of Fe-doping (oxy)hydroxides by previous experiment and theoretical calculation results [37,38]. This drives us to explore the influence of mole ratios of Ni/Fe in NiFe-LDH on the PEC activity of BiVO4/NiFe-LDH photoanode.…”

Section: Resultsmentioning

confidence: 96%

“…The high activity for PEC water splitting can last for over 30 h. The enhanced PEC performance is attributed to the synergistic effect of the superior charge separation efficiency facilitated by porous film and the excellent water oxidation activity resulting from NiFe-LDH nanosheet arrays OEC layer. Moreover, considering that the element Fe plays a critical role in enhancing OER active (oxy)hydroxides [37,38], the effect of Fe/Ni ratio on PEC performance of BiVO4/NiFe-LDH photoanode is discussed in detail. Furthermore, it is found that the performance of ternary NiFeCo-LDH fabricated by incorporating a certain amount of Co 2+ cation into NiFe-LDH as OEC can be further enhanced, with the photocurrent density of 4.45 mA cm −2 at 1.23 V vs. RHE, which is the highest among reported un-doped BiVO4-based photoanodes known to date.…”

Section: Introductionmentioning

confidence: 99%

Promoting charge carrier utilization by integrating layered double hydroxide nanosheet arrays with porous BiVO4 photoanode for efficient photoelectrochemical water splitting

Huang

Xin

et al. 2017

Sci. China Mater.

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The increasing exploration of renewable and clean power sources have driven the development of highly active materials for photoelectrochemical (PEC) water splitting. However, it is still a great challenge to enhance the charge utilization. Herein, we report a facile method to fabricate composite photoanode with porous BiVO4 film as the photon absorber and layered double hydroxide (LDH) nanosheet arrays as the oxygen-evolution cocatalysts (OECs). The as-prepared BiVO4/NiFe-LDH photoanode shows an excellent performance for PEC water splitting benefitting from the synergistic effect of the superior charge separation efficiency facilitated by porous BiVO4 film and the excellent water oxidation activity resulting from LDH nanosheet arrays. A photocurrent density is 4.02 mA cm −2 at 1.23 V vs. the reversible hydrogen electrode (RHE). Furthermore, the O2 evolution rate at the surface of BiVO4/NiFe-LDH photoanode is as high as 29.6 µmol h −1 cm −2 and the high activity for water oxidation is maintained for over 30 h. Impressively, the performance of the as-fabricated composite photoanode for PEC water splitting can be further enhanced through incorporating a certain amount of Co 2+ cation into NiFe-LDH as OEC. The photocurrent density is achieved up to 4.45 mA cm −2 at 1.23 V vs. RHE. This value is the highest yet reported for un-doped BiVO4-based photoanodes so far.

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“…Further increasing the potential before the onset of OER, the Ni 2+ was oxidized to Ni 3+ ; however, the Fe cations remain as Fe 3+ . In other words, the NiFe LDHs was oxidized into γ‐Ni 1− x Fe x OOH ( x < 25%) and NiFe LDH structure transformed into the Fe‐doped γ‐NiOOH structure leading to the shift for adsorption energies of oxygen intermediates 113. DFT+U calculation results further demonstrated that Fe‐doped LDHs changed the composition and structure of the oxidized catalyst 113.…”

Section: Electrocatalytic Water Splittingmentioning

confidence: 95%

“…In other words, the NiFe LDHs was oxidized into γ‐Ni 1− x Fe x OOH ( x < 25%) and NiFe LDH structure transformed into the Fe‐doped γ‐NiOOH structure leading to the shift for adsorption energies of oxygen intermediates 113. DFT+U calculation results further demonstrated that Fe‐doped LDHs changed the composition and structure of the oxidized catalyst 113. Meanwhile, DFT+U calculation of the OER overpotential explained the reason for the enhancement OER activity of Ni 1− x Fe x OOH with the increase of Fe content.…”

Section: Electrocatalytic Water Splittingmentioning

confidence: 99%

Recent Progress on Layered Double Hydroxides and Their Derivatives for Electrocatalytic Water Splitting

et al. 2018

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Layered double hydroxide (LDH)‐based materials have attracted widespread attention in various applications due to their unique layered structure with high specific surface area and unique electron distribution, resulting in a good electrocatalytic performance. Moreover, the existence of multiple metal cations invests a flexible tunability in the host layers; the unique intercalation characteristics lead to flexible ion exchange and exfoliation. Thus, their electrocatalytic performance can be tuned by regulating the morphology, composition, intercalation ion, and exfoliation. However, the poor conductivity limits their electrocatalytic performance, which therefore has motivated researchers to combine them with conductive materials to improve their electrocatalytic performance. Another factor hampering their electrocatalytic activity is their large lateral size and the bulk thickness of LDHs. Introducing defects and tuning electronic structure in LDH‐based materials are considered to be effective strategies to increase the number of active sites and enhance their intrinsic activity. Given the unique advantages of LDH‐based materials, their derivatives have been also used as advanced electrocatalysts for water splitting. Here, recent progress on LDHs and their derivatives as advanced electrocatalysts for water splitting is summarized, current strategies for their designing are proposed, and significant challenges and perspectives of LDHs are discussed.

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Identification of Highly Active Fe Sites in (Ni,Fe)OOH for Electrocatalytic Water Splitting

Cited by 2,101 publications

References 73 publications

Towards Versatile and Sustainable Hydrogen Production through Electrocatalytic Water Splitting: Electrolyte Engineering

Towards Versatile and Sustainable Hydrogen Production through Electrocatalytic Water Splitting: Electrolyte Engineering

Promoting charge carrier utilization by integrating layered double hydroxide nanosheet arrays with porous BiVO4 photoanode for efficient photoelectrochemical water splitting

Recent Progress on Layered Double Hydroxides and Their Derivatives for Electrocatalytic Water Splitting

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