Promoting the Water Oxidation Catalysis by Synergistic Interactions between Ni(OH)<sub>2</sub> and Carbon Nanotubes

Wang, Lei; Chen, Hong; Daniel, Quentin; Duan, Lele; Philippe, Bertrand; Yang, Yi; Rensmo, Håkan; Sun, Licheng

doi:10.1002/aenm.201600516

Cited by 71 publications

(65 citation statements)

References 59 publications

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“…Therefore, all subsequente lectrocatalytic tests were only focused on the optimal CP@Ni(OH) 2 electrode. After preactivation, the CP@Ni(OH) 2 electrode only needs overpotentials of 1.54 (h 10 = 308 mV) and 1.57 V( h 20 = 338 mV) to attain current densities of 10 and 20 mA cm À2 ,r espectively;t hese values compare favorably to those of otherN i-based OER catalysts recently reported in the literature, such as a-Ni(OH) 2 hollow spheres (h 10 = 331 mV), [34] b-Ni(OH) 2 nanoplates (h 10 = 444 mV), [34] b-Ni(OH) 2 nanoparticles (h 10 = 340 mV), [36] b-Ni(OH) 2 porousn ano-plates (h 10 = 360 mV), [29] NiFe 2 O 4 /a-Ni(OH) 2 compounds (h 10 = 340 mV), [43] Ni 2 Pn anowires (h 10 = 400 mV), [30] and electrodeposited Ni-P thin films (h 10 = 344 mV), [31] although they are not as good as those of b-Ni(OH) 2 /O-MWCNT hybrids (h 10 = 270 mV) [37] and Ni-P porousnanoplates (h 10 = 300 mV) [29] (Table S2). For comparison, the OER activities of bare CP andC P/RuO 2 electrodes were also measured.…”

Section: Resultsmentioning

confidence: 99%

“…In this context, considerable research efforts have recently been de-voted to the search for efficient and inexpensive OER catalysts comprising earth-abundant elements, including transitionmetal oxides, [8][9][10] hydroxides, [11][12][13] perovskites, [14,15] phosphates, [16,17] sulfides, [18,19] and recently reported phosphides. [33][34][35][36][37][38][39][40] For example, Stern and Hu compared the OER performance of bulk Ni(OH) 2 films to that of Ni(OH) 2 nanoparticles and found that the Ni(OH) 2 nanoparticles only neededasmall overpotential (h)o f3 00 mV to deliver ac urrent density of 10 mA cm À2 (h 10 ), and thus, they substantially outperformed bulk Ni(OH) 2 films and demonstratedt he benefito fn anostructuring. Previous work on the OER performance of Ni(OH) 2 was primarily focusedo ne lectrodepositeda nd physically depositedt hin films.…”

Section: Introductionmentioning

confidence: 99%

“…[33][34][35][36][37][38][39][40] For example, Stern and Hu compared the OER performance of bulk Ni(OH) 2 films to that of Ni(OH) 2 nanoparticles and found that the Ni(OH) 2 nanoparticles only neededasmall overpotential (h)o f3 00 mV to deliver ac urrent density of 10 mA cm À2 (h 10 ), and thus, they substantially outperformed bulk Ni(OH) 2 films and demonstratedt he benefito fn anostructuring. [37] The excellent OER activity was ascribed to as ynergistic effect between Ni(OH) 2 and the MWCNTsa sw ell as the presence of oxygencontaining groups (e.g.,k etone and carboxylate) on the MWCNTst hat facilitated protont ransfer during the OER. [34] Although nanostructured Ni(OH) 2 is able to provide ag reater surfacea rea and more electrocatalytically active sites to allow for easy access to the electrolyte, the intrinsic electrical conductivity of Ni(OH) 2 is very poor such that fast charge transfer is difficult to achieve.…”

Section: Introductionmentioning

confidence: 99%

“…[34] Although nanostructured Ni(OH) 2 is able to provide ag reater surfacea rea and more electrocatalytically active sites to allow for easy access to the electrolyte, the intrinsic electrical conductivity of Ni(OH) 2 is very poor such that fast charge transfer is difficult to achieve. [33,34,37,39] Moreover,m ost Ni(OH) 2 nanostructures reported for use as OER catalysts were produced in the form of powders, [33][34][35][36][37]39] and Ni(OH) 2 nanostructures directly grown on current collectors have been rarely explored. [37] The excellent OER activity was ascribed to as ynergistic effect between Ni(OH) 2 and the MWCNTsa sw ell as the presence of oxygencontaining groups (e.g.,k etone and carboxylate) on the MWCNTst hat facilitated protont ransfer during the OER.…”

Section: Introductionmentioning

confidence: 99%

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Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Xiong

Liu

2017

Chemistry An Asian Journal

151

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Vertically aligned Ni(OH) nanosheets were grown on carbon paper (CP) current collectors through a simple and cost-effective hydrothermal approach. The as-grown nanosheets are porous and highly crystallized. If used as a monolithic electrode for electrochemical water oxidation in alkaline solution, the carbon paper supported Ni(OH) nanosheets [CP@Ni(OH) ] exhibit high electrocatalytic activity and excellent long-term stability. The electrode can attain an anodic current density of 20 mA cm at a low overpotential of 338 mV, comparable to that of state-of-the-art RuO nanocatalysts supported on CP (CP/RuO ) with the same catalyst loading. Significantly, CP@Ni(OH) shows much better long-term stability than CP/RuO upon continuous galvanostatic electrolysis, particularly at a high industry-relevant current density such as 100 mA cm . CP@Ni(OH) can sustain water oxidation at 100 mA cm for 50 h without any degradation, whereas the performance of CP/RuO is much poorer and deteriorates gradually over time. CP@Ni(OH) electrodes hold substantial promise for use as low-costing water oxidation anodes in electrolyzers.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Xiong

Liu

2017

Chemistry An Asian Journal

151

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“…First, linear sweep voltammetry (LSV) was conducted to test the electrochemical behavior of the NiFe/Cu 2 O NWs/CF electrode in 1.0 m KOH, as shown in Figure 6a . [31] Cyclic voltammograms of the non-faradaic region were recorded at various scan rates, and the C dl and ECSA of the NiFe/Cu 2 ON Ws/CF electrode were calculated to be 98 mF cm À2 and 2450 cm 2 ,r espectively.S uch al arge ECSA is of great help for enhancing the catalytic activity for the OER. In contrast, the OER did not proceed with the Cu 2 ON Ws/CF electrode until the oxidation potentialw as increased to 1.55 V versusR HE (black line).…”

Section: Resultsmentioning

confidence: 99%

Highly Active Three‐Dimensional NiFe/Cu₂O Nanowires/Cu Foam Electrode for Water Oxidation

2017

Self Cite

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Water splitting is of paramount importance for exploiting renewable energy-conversion and -storage systems, but is greatly hindered by the kinetically sluggish oxygen evolution reaction (OER). In this work, a three-dimensional, highly efficient, and durable NiFe/Cu O nanowires/Cu foam anode (NiFe/Cu O NWs/CF) for water oxidation in 1.0 m KOH was developed. The obtained electrode exhibited a current density of 10 mA cm at a uniquely low overpotential of η=215 mV. The average specific current density (j ) was estimated, on the basis of the electrocatalytically active surface area, to be 0.163 mA cm at η=310 mV. The electrode also displayed a low Tafel slope of 42 mV decade . Moreover, the NiFe/Cu O NWs/CF electrode could maintain a steady current density of 100 mA cm for 50 h at an overpotential of η=260 mV. The outstanding electrochemical performance of the electrode for the OER was attributed to the high conductivity of the Cu foam and the specific structure of the electrode with a large interfacial area.

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In Situ Growth of Ceria on Cerium–Nitrogen–Carbon as Promoter for Oxygen Evolution Reaction

Wang

Shan

et al. 2017

Adv Materials Inter

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developing efficient and economical catalysts comprised of easily obtained materials for the OER is becoming very crucial for water splitting devices, in which the water-splitting catalysts made up of earthabundant elements have been paid a lot of attention. [2] Layer double hydroxide (LDH,posed of layers of divalent and trivalent metal cations coordinated to hydroxide anions, with guest anions intercalated between the layers, [3] displaying a promising structure for efficient electrocatalysts. It has been confirmed that exfoliated LDH shows higher electrocatalytic activity for the OER in alkaline environments than commercial precious metal based catalysts, [4] 3D self-supported LDH based materials showed outstanding catalytic activity and lifetime for OER, [5] and trinary NiCoFe-LDH exhibited an enhanced bifunctional performance on electrocatalysis. [6] Growing enthusiasm is devoted to optimizing the structure and composition of LDH materials themselves. However, studies on hybrid structure formed with other materials (such as carbon materials) almost lack of creativity and deep interpretation, especially for the effects of promoter acts on this process.Pure carbon materials exhibit scarcely any activity for the OER. [7] Alternatively, hybrid electrocatalysts of transition metal compounds with carbon materials (e.g., carbon nanotubes, [8] porous carbon, [8b,9] and graphene oxide (GO) [10] ) have been extensively investigated to improve the electrocatalytic activity for the OER, where carbon materials play a role of a promoter, most of the time. Beyond that, metal-nitrogen-carbon (MNC) materials are jumping into our sight as the greatest potential electrocatalysts. [11] The active sites are ascribed to central metal ions stabilized by nitrogen functional groups on carbonaceous surfaces, showing distinct interactions with oxygen molecules and the intermediates. [12] On the other hand, cerium-based materials have been reported to have the reversible surface oxygen ion exchange, good electronic/ionic conductivity, and high oxygen-storage capacities because of the flexible transition between the Ce 3+ and Ce 4+ oxidation states. [13] Recently, Li's group developed a novel electrocatalyst for OER by supporting FeOOH/CeO 2 heterolayered nanotubes on nickel foam and exhibited high performance. [14] They also demonstrated the unique high oxygen-storage capacitance properties of CeO 2 , such that CeO 2 can straightway absorb the oxygen produced Rational design and controlled synthesis of a promoter is a unique and more widely applicable approach to materials development for significant energy applications such as electrocatalytic oxygen evolution reaction. This study reports a novel promoter based on ceria in situ growth on cerium-nitrogencarbon (CeO 2 @CeNC) for an oxygen evolution electrocatalyst. Composited with NiFe-LDH (optimal mass ratio of layer double hydroxide (LDH) and CeO 2 @CeNC is 2), the hybrid material (NiFe-LDH/CeO 2 @CeNC) exhibits excellent activity for oxygen evolution superior to those of most n...

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Promoting the Water Oxidation Catalysis by Synergistic Interactions between Ni(OH)₂ and Carbon Nanotubes

Cited by 71 publications

References 59 publications

Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Highly Active Three‐Dimensional NiFe/Cu₂O Nanowires/Cu Foam Electrode for Water Oxidation

In Situ Growth of Ceria on Cerium–Nitrogen–Carbon as Promoter for Oxygen Evolution Reaction

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Promoting the Water Oxidation Catalysis by Synergistic Interactions between Ni(OH)2 and Carbon Nanotubes

Cited by 71 publications

References 59 publications

Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Vertically Aligned Porous Nickel(II) Hydroxide Nanosheets Supported on Carbon Paper with Long‐Term Oxygen Evolution Performance

Highly Active Three‐Dimensional NiFe/Cu2O Nanowires/Cu Foam Electrode for Water Oxidation

In Situ Growth of Ceria on Cerium–Nitrogen–Carbon as Promoter for Oxygen Evolution Reaction

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Promoting the Water Oxidation Catalysis by Synergistic Interactions between Ni(OH)₂ and Carbon Nanotubes

Highly Active Three‐Dimensional NiFe/Cu₂O Nanowires/Cu Foam Electrode for Water Oxidation