In Situ Construction of a Mn2+-Doped Ni3S2 Electrode with Highly Enhanced Urea Oxidation Reaction Performance

Yang, Han; Yuan, Mengwei; Sun, Zemin; Wang, Di; Liu, Lin; Li, Huifeng; Sun, Genban

doi:10.1021/acssuschemeng.0c02160

Cited by 78 publications

(58 citation statements)

References 60 publications

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“…Therefore, compared to acidic or neutral UOR, alkaline UOR is more promising. For alkaline UOR, owing to the intrinsic higher activities, Ni-based catalysts (Ni-containing metals, 80–84 oxides, 85–90 hydroxides, 91–97 sulfides, 98–102 phosphides, 103–105 selenides, 106–108 nitrides, 109–113 etc. ) have been more widely investigated among all transition metal-based catalysts.…”

Section: Reaction Mechanism Of the Uormentioning

confidence: 99%

Strategies for designing more efficient electrocatalysts towards the urea oxidation reaction

et al. 2022

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Section: Reaction Mechanism Of the Uormentioning

confidence: 99%

Strategies for designing more efficient electrocatalysts towards the urea oxidation reaction

et al. 2022

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“…The Ni 2p 3/2 and Ni 2p 1/2 bands of the catalyst are at 856.3 and 874.1 eV, respectively (Figure 3c). The corresponding satellite peaks are located at 861.9 and 880.6 eV [41–43] . Similar to that of iron, after OER, the bands present obvious red‐shifts.…”

Section: Resultsmentioning

confidence: 77%

“…The corresponding satellite peaks are located at 861.9 and 880.6 eV. [41][42][43] Similar to that of iron, after OER, the bands present obvious red-shifts. Figure 3d presents the oxygen XPS band for the catalyst Fe 3 + /Ni 2 + À PC-1 : 2 before and after OER.…”

Section: Synthesis and Characterizationmentioning

confidence: 81%

A Wet Impregnation Strategy for Advanced FeNi‐Based Electrocatalysts towards Oxygen Evolution

et al. 2020

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In this study, the typical wet impregnation method was employed to prepare advanced electrocatalysts for oxygen evolution reaction (OER). The preparation process is easy‐operation and doesn't require any complex synthesis steps. This strategy was demonstrated with Fe3+/Ni2+ loaded on porous carbon as an example. The thus formed pre‐catalyst was in situ activated in the electrochemical test process, during which the electrochemically active species for OER are achieved. With the optimized catalyst, a current density of 10 mA.cm−2 can be obtained at an overpotential of 275 mV. This catalytic performance is close to or even better than the benchmarked RuO2 and IrO2 catalysts. Especially, the catalyst also exhibits good catalytic stability. This study presents a new non‐chemical synthesis route for advanced oxygen evolution catalysts.

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“…Urea is regarded as a potential energy source because it possesses the following: high energy density, high hydrogen content, abundant reserves, highly stable, easily stored and transported [108, 109]. Interestingly, urea is considered as an advanced hydrogen carrier because it utilizes a lower cell potential (0.37 V) than the water‐splitting reaction (1.23 V) [108, 110]. The electrooxidation reaction of urea is shown in Equation 5 and 6 [111]:

true Anodic reaction : CO (NH_{2})_{2} + 6 OH^{-} \to normalN_{2} + CO_{2} + 5 H_{2} normalO + 6 e^{-} normalE^{θ} = - 0.746 normalV

true Cathodic reaction : 6 H_{2} normalO + 6 e^{-} \to 3 H_{2} + 6 OH^{-} normalE^{θ} = - 0.83 normalV

…”

Section: General Applications Of Niseqdmentioning

confidence: 99%

Nickel Selenide Quantum Dot Applications in Electrocatalysis and Sensors

et al. 2020

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Quantum dots (QDs) are semiconducting materials with diameters ranging from 2-10 nm. Amongst these QDs, nickel selenide quantum dot (NiSeQD) materials have gained much interest from researchers over the past few years due to their outstanding properties. These include excellent catalytic activity, good electrical conductivity for charge transfer, and excellent thermodynamic stability. NiSeQD material is relatively cheap, less toxic, and can be synthesised easily. Due to the fascinating and remarkable properties of NiSeQD, the material has been applied in various electrochemical fields, including hydrogen evolution reaction (HER), oxygen evolution reaction (OER), and solar cells. This review focuses on the application of NiSeQD and its composites in the various analytical fields in the search for alternative renewable sources of energy. Interestingly, NiSeQD material can be modified with different materials to improve its sensitivity, reactivity, and limit of detection. The effects of modification with other materials such as iron (Fe), cobalt (Co), and graphene (GN) are mentioned. Additionally, the application of NiSeQD in glucose sensing is discussed briefly. In these aforementioned applications, NiSeQD has shown excellent electrocatalytic capability with satisfactory detection limits and good conductivity. Thus, further exploration of it to other fields is essential. This review highlights the importance of NiSeQD in water purification, and no report has been documented in the literature on its application in water purification. Some gaps are still open for the use of NiSeQD material as an electroactive platform for sensing devices in water treatment.

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In Situ Construction of a Mn²⁺-Doped Ni₃S₂ Electrode with Highly Enhanced Urea Oxidation Reaction Performance

Cited by 78 publications

References 60 publications

Strategies for designing more efficient electrocatalysts towards the urea oxidation reaction

Strategies for designing more efficient electrocatalysts towards the urea oxidation reaction

A Wet Impregnation Strategy for Advanced FeNi‐Based Electrocatalysts towards Oxygen Evolution

Nickel Selenide Quantum Dot Applications in Electrocatalysis and Sensors

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