Ionothermal Route to Phase-Pure RuB<sub>2</sub> Catalysts for Efficient Oxygen Evolution and Water Splitting in Acidic Media

Ding, Chunmei; Liu, Tingting; Wang, Pengyan; Zhao, Jiahuan; Zhang, Chengtian; Cheng, Ruilin; Li, Wenqiang; Ji, Pengxia; Pu, Zonghua; Mu, Shichun

doi:10.1021/acsenergylett.0c01384

Cited by 129 publications

(113 citation statements)

References 50 publications

(74 reference statements)

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“…From the deconvoluted spectrum of Ru 3p state, the couple peaks at 462.1 and 484.3 eV are associated with Ru 3p 3/2 and Ru 3p 1/2 , respectively (Figure 2 c). [3, 18] Figure 2 d shows that the separate subpeaks at 163.0 and 164.2 eV are consistent with S 2p 3/2 and S 2p 1/2 states, respectively [19] . To compare the chemical states of heterostructure material with phase‐pure materials, further XPS analyses were conducted.…”

Section: Figurementioning

confidence: 80%

“…As for the hydrogen production, the acidic water splitting devices employing mature proton exchange membrane (PEM) technology afford excellent hardware environment for large‐scale commercial applications [1a, 2] . The use of PEM and favorable reaction mechanism bring multiple strengths, such as cost advantage, high proton conduction, fewer side effects and convenient gas separation [2b, 3] . However, both electrodes of PEM‐water splitting (PEMWS) devices require certain electrocatalysts to effectively facilitate the sluggish kinetic processes [1a, 4] .…”

Section: Figurementioning

confidence: 99%

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Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

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Theoretical calculations unveil the charge redistribution over abundant interfaces and the enhanced electronic states of Ru/RuS2 heterostructure. The resulting surface electron‐deficient Ru sites display optimized adsorption behavior toward diverse reaction intermediates, thereby reducing the thermodynamic energy barriers. Experimentally, for the first time the laminar Ru/RuS2 heterostructure is rationally engineered by virtue of the synchronous reduction and sulfurization under eutectic salt system. Impressively, it exhibits extremely high catalytic activity for both OER (201 mV @ 10 mA cm−2) and HER (45 mV @ 10 mA cm−2) in acidic media due to favorable kinetics and excellent specific activity, consequently leading to a terrific performance in acidic overall water splitting devices (1.501 V @ 10 mA cm−2). The in‐depth insight into the internal activity origin of interfacial effect could offer precise guidance for the rational establishment of hybrid interfaces.

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Section: Figurementioning

confidence: 80%

Section: Figurementioning

confidence: 99%

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

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“…But the oxidation behavior at high voltage would cause devitalization, and the effusion of lattice oxygen would result in the dissolution of active species, rendering them unstable during OER process [10] . Thus, designing oxygen‐free Ru‐based catalysts with suitable morphology and electron structure might alleviate the deactivation behavior, meanwhile promote their intrinsic activity and durability [3, 11] …”

Section: Figurementioning

confidence: 99%

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

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“…The results showed that RuB 2 needed less energy for the rate-determining step (formation of *OOH), so the OER activity was improved (Figure 3d, e). [31] In addition, the OER activity of RuTe 2 was also [8] and c) RuP 2 @PNC [20a] used in DFT calculations and calculated free energy diagrams of the catalyst samples for HER. [17b] Reproduced with permission.…”

Section: Gibbs Free Energy Of Key Intermediatesmentioning

confidence: 99%

“…d), e) Free energetic pathways of RuB 2 and RuO 2 for acidic OER at U = 0 V. Reproduced with permission. [31] Copyright: 2020, American Chemical Society. f) CO 2 RR and g) nitrite reduction on pure Pd (111) and TeÀ Pd (111) surfaces.…”

Section: Gibbs Free Energy Of Key Intermediatesmentioning

confidence: 99%

Anion Modulation of Pt‐Group Metals and Electrocatalysis Applications

Chen

Zhu

2021

Chemistry A European J

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Pt-group metal (PGM) electrocatalysts with unique electronic structures and irreplaceable comprehensive properties play crucial roles in electrocatalysis. Anion engineering can create a series of PGM compounds (such as RuP 2 , IrP 2 , PtP 2 , RuB 2 , Ru 2 B 3 , RuS 2 , etc.) that provide a promising prospect for improving the electrocatalytic performance and use of Ptgroup noble metals. This review seeks the electrochemical activity origin of anion-modulated PGM compounds, and systematically analyzes and summarizes their synthetic strategies and energy-relevant applications in electrocatalysis. Orientation towards the sustainable development of nonfossil resources has stimulated a blossoming interest in the design of advanced electrocatalysts for clean energy conversion. The anion-modulated strategy for Pt-group metals (PGMs) by means of anion engineering possesses high flexibility to regulate the electronic structure, providing a promising prospect for constructing electrocatalysts with superior activity and stability to satisfy a future green electrochemical energy conversion system. Based on the previous work of our group and others, this review summarizes the up-to-date progress on anion-modulated PGM compounds (such as RuP 2 , IrP 2 , PtP 2 , RuB 2 , Ru 2 B 3 , RuS 2 , etc.) in energy-related electrocatalysis from the origin of their activity and synthetic strategies to electrochemical applications including hydrogen evolution reaction (HER), oxygen evolution reaction (OER), oxygen reduction reaction (ORR), hydrogen oxidation reaction (HOR), N 2 reduction reaction (NRR), and CO 2 reduction reaction (CO 2 RR). At the end, the key problems, countermeasures and future development orientations of anionmodulated PGM compounds toward electrocatalytic applications are proposed.

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Ionothermal Route to Phase-Pure RuB₂ Catalysts for Efficient Oxygen Evolution and Water Splitting in Acidic Media

Cited by 129 publications

References 50 publications

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Anion Modulation of Pt‐Group Metals and Electrocatalysis Applications

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Ionothermal Route to Phase-Pure RuB2 Catalysts for Efficient Oxygen Evolution and Water Splitting in Acidic Media

Cited by 129 publications

References 50 publications

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Regulative Electronic States around Ruthenium/Ruthenium Disulphide Heterointerfaces for Efficient Water Splitting in Acidic Media

Anion Modulation of Pt‐Group Metals and Electrocatalysis Applications

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Ionothermal Route to Phase-Pure RuB₂ Catalysts for Efficient Oxygen Evolution and Water Splitting in Acidic Media