Activity–Stability Trends for the Oxygen Evolution Reaction on Monometallic Oxides in Acidic Environments

Danilovic, Nemanja; Subbaraman, Ram; Chang, Kee‐Chul; Chang, Seo Hyoung; Kang, Yijin; Snyder, Joshua; Paulikas, A. P.; Strmčnik, Dušan; Kim, Yong‐Tae; Myers, Deborah J.; Stamenković, Vojislav R.; Marković, Nenad M.

doi:10.1021/jz501061n

Cited by 608 publications

(704 citation statements)

References 21 publications

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“…A trade‐off between the activity and stability is reported for the OER in acidic environments, even for the most active oxides, IrO 2 and RuO 2 149. As expected from the Pourbaix diagram shown in Figure 11,151 the cationic state of the metals is thermodynamically more favored at lower pH levels, which is consistent with the nature of their dissolution into solution.…”

Section: Oxygen Evolution Reaction (Oer)supporting

confidence: 60%

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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)supporting

confidence: 60%

“…Improving not only the activity but also the stability is a challenge for OER electrodes, particularly in acidic149 and near‐neutral pH150 environments. A trade‐off between the activity and stability is reported for the OER in acidic environments, even for the most active oxides, IrO 2 and RuO 2 149.…”

Section: Oxygen Evolution Reaction (Oer)mentioning

confidence: 99%

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

2017

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“…At high pH ferrous metals are materials of choice, as they are thermodynamically stable [43]. For studied materials, more stable electrodes were typically less active, confirming at least in this case the earlier mentioned inverse activity-stability correlation [36]. Due to the fact that Ru is not stable, most of the research on the acidic OER has been devoted to optimization of Ir-based catalysts.…”

Section: Fast Screening Of Noble Metal Based Oer Catalyst Activity Ansupporting

confidence: 53%

“…A thermodynamic explanation for the observed oxide dissolution during OER was recently provided by Binninger et al [35]. The important outcome of these studies is that in the region of OER potentials, the stability of the material is not only defined by its "nobility," and that there are deviations from the inverse relationship of activity and stability often suggested in literature [36]. As an example, Au as the noblest of the metals [37] is neither stable during OER in acidic media nor active (at least in the classical view of the activity using exchange current density or onset potential of OER) [38][39][40].…”

Section: Fast Screening Of Noble Metal Based Oer Catalyst Activity Anmentioning

confidence: 91%

MAXNET Energy – Focusing Research in Chemical Energy Conversion on the Electrocatlytic Oxygen Evolution

Auer

Cap

Antonietti

et al. 2015

Green

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MAXNET Energy is an initiative of the Max Planck society in which eight Max Planck institutes and two external partner institutions form a research consortium aiming at a deeper understanding of the electrocatalytic conversion of small molecules. We give an overview of the activities within the MAXNET Energy research consortium. The main focus of research is the electrocatalytic water splitting reaction with an emphasis on the anodic oxygen evolution reaction (OER). Activities span a broad range from creation of novel catalysts by means of chemical or material synthesis, characterization and analysis applying innovative electrochemical techniques, atomistic simulations of state-of-the-art x-ray spectroscopy up to model-based systems analysis of coupled reaction and transport mechanisms. Synergy between the partners in the consortium is generated by two modes of cooperation – one in which instrumentation, techniques and expertise are shared, and one in which common standard materials and test protocols are used jointly for optimal comparability of results and to direct further development. We outline the special structure of the research consortium, give an overview of its members and their expertise and review recent scientific achievements in materials science as well as chemical and physical analysis and techniques. Due to the extreme conditions a catalyst has to endure in the OER, a central requirement for a good oxygen evolution catalyst is not only its activity, but even more so its high stability. Hence, besides detailed degradation studies, a central feature of MAXNET Energy is a standardized test setup/protocol for catalyst stability, which we propose in this contribution

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“…Unlike Ni(abt) 2 for OER, each step is moderate for the Co site of on‐MoS 2 Co(abt) 2 (see Figure 5c). The potential‐determining step is the process from OH* to O* and the overpotential η is only 0.43 V, comparable to traditional precious metal‐based OER catalysts in a range of about 0.3–0.7 V,51, 58, 59 showing that OER can be efficiently catalyzed at the Co site of on‐MoS 2 Co(abt) 2 . Our calculations show that OER can be catalyzed by Co(abt) 2 along the four‐electron pathway.…”

Section: Resultsmentioning

confidence: 82%

Exploitation of the Large‐Area Basal Plane of MoS₂ and Preparation of Bifunctional Catalysts through On‐Surface Self‐Assembly

Zhao

Shi

et al. 2017

Advanced Science

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The development of nonprecious electrochemical catalysts for water splitting is a key step to achieve a sustainable energy supply for the future. Molybdenum disulfide (MoS2) has been extensively studied as a promising low‐cost catalyst for hydrogen evolution reaction (HER), whereas HER is only catalyzed at the edge for pristine MoS2, leaving a large area of basal plane useless. Herein, on‐surface self‐assembly is demonstrated to be an effective, facile, and damage‐free method to take full advantage of the large ratio surface of MoS2 for HER by using multiscale simulations. It is found that as supplement of edge sites of MoS2, on‐MoS2 M(abt)2 (M = Ni, Co; abt = 2‐aminobenzenethiolate) owns high HER activity, and the self‐assembled M(abt)2 monolayers on MoS2 can be obtained through a simple liquid‐deposition method. More importantly, on‐surface self‐assembly provides potential application for overall water splitting once the self‐assembled systems prove to be of both HER and oxygen evolution reaction activities, for example, on‐MoS2 Co(abt)2. This work opens up a new and promising avenue (on‐surface self‐assembly) toward the full exploitation of the basal plane of MoS2 for HER and the preparation of bifunctional catalysts for overall water splitting.

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Activity–Stability Trends for the Oxygen Evolution Reaction on Monometallic Oxides in Acidic Environments

Cited by 608 publications

References 21 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

MAXNET Energy – Focusing Research in Chemical Energy Conversion on the Electrocatlytic Oxygen Evolution

Exploitation of the Large‐Area Basal Plane of MoS₂ and Preparation of Bifunctional Catalysts through On‐Surface Self‐Assembly

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Activity–Stability Trends for the Oxygen Evolution Reaction on Monometallic Oxides in Acidic Environments

Cited by 608 publications

References 21 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

MAXNET Energy – Focusing Research in Chemical Energy Conversion on the Electrocatlytic Oxygen Evolution

Exploitation of the Large‐Area Basal Plane of MoS2 and Preparation of Bifunctional Catalysts through On‐Surface Self‐Assembly

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Exploitation of the Large‐Area Basal Plane of MoS₂ and Preparation of Bifunctional Catalysts through On‐Surface Self‐Assembly