In Situ Electrosynthesis of MAX‐Derived Electrocatalysts for Superior Hydrogen Evolution Reaction

Sheng, Minhao; Bin, Xiaoqing; Yang, Yawei; Tang, Yi; Que, Wenxiu

doi:10.1002/smll.202203471

Cited by 20 publications

(11 citation statements)

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“…Transition-metal-based electrocatalysts have shown great potential for overall water splitting over the past few years. Various oxides (MoO x ) [ 9 ], hydroxides (Ni(OH) 2 ) [ 10 , 11 ], sulfides (MoS 2 ) [ 12 ], selenides (MoSe 2 ) [ 13 ], nitrides (VN) [ 14 ], and carbides (MXene) [ 15 , 16 ] materials have been extensively reported as water splitting electrocatalysts. Among the aforementioned catalysts, transition metal phosphides (TMPs) possess a hydrogenase-like structure, and are regarded as promising nonprecious electrocatalysts for overall water splitting [ 17 , 18 , 19 , 20 , 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

et al. 2023

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We adopted a simple one-step electrochemical deposition to acquire an efficient nickel cobalt phosphorus (NiCoP) catalyst, which avoided the high temperature phosphatization engineering involved in the traditional synthesis method. The effects of electrolyte composition and deposition time on electrocatalytic performance were studied systematically. The as-prepared NiCoP achieved the lowest overpotential (η10 = 111 mV in the acidic condition and η10 = 120 mV in the alkaline condition) for the hydrogen evolution reaction (HER). Under 1 M KOH conditions, optimal oxygen evolution reaction (OER) activity (η10 = 276 mV) was also observed. Furthermore, the bifunctional NiCoP catalyst enabled a high-efficiency overall water-splitting by applying an external potential of 1.69 V. The surface valence and structural evolution of NiCoP samples with slowly decaying stability under alkaline conditions are revealed by XPS. The NiCoP is reconstructed into the Ni(Co)(OH)2 (for HER) and Ni(Co)OOH (for OER) on the surface with P element loss, acting as real “active sites”.

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Section: Introductionmentioning

confidence: 99%

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

et al. 2023

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“…For the C1s spectrum, the peak at 281.5 eV of Ti 2 AlC matches with Ti–C, which is shifted to a positive binding energy value (281.7 eV) in Ti 1.2 Nb 0.8 AlC due to the influence of Nb–C bond. [ 46 ] The other peaks about 284.8, 285.8, and 289 eV have contributions from the bonds of C–C, C—O, and C=O, respectively. As a result, the foreign atoms with different electronegativity compared to host atoms will change the distribution of the electron cloud and lead to the formation of electric dipoles on the EM field, contributing to EM wave dissipation.…”

Section: Resultsmentioning

confidence: 99%

Structural Engineering Enabled Bimetallic (Ti_1‐_yNb_y)₂AlC Solid Solution Structure for Efficient Electromagnetic Wave Absorption in Gigahertz

Zhao

et al. 2023

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Microstructures play a critical role to influence the polarization behavior of dielectric materials, which determines the electromagnetic response ability in gigahertz. However, the relationship between them, especially in the solid‐solution structures is still absent. Herein, a series of (Ti1‐yNby)2AlC MAX phase solid solutions with nano‐laminated structures have been employed to illuminate the aforementioned problem. The relationship has been investigated by the lattice distortion constructed via tuning the composition from Ti to Nb in the M‐site atomic layer. Experimental characterizations indicated that the dielectric response behaviors between declined conduction loss and boosted polarization loss can be well balanced by niobium atom manipulative solid‐solution engineering, which is conducive to impedance matching and electromagnetic absorption performance. Theoretical calculation further proved that the origin of electric dipoles is ascribed to the charge density differences resulting from the altered microscopic atomic distribution. As a result, the Ti1.2Nb0.8AlC exhibits the mostly optimized microwave absorption property, in which a minimum reflection loss of −42 dB and an effective absorption bandwidth of 4.3 GHz under an ultra‐thin thickness of 1.4 mm can be obtained. This work provides insight into the structural engineering in modifying electromagnetic response performance at gigahertz and which can be expanded to other solid‐solution materials.

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“…The prepared MoS 2 ‐Ti 3 C 2 MXene electrocatalyst possessed abundant active sites, excellent conductivity and structural stability. The activity of the MAX phase was investigated [97] . Max‐derived electrocatalysts were prepared using a two‐step in situ electrosynthesis process, namely electrochemical etching and deposition.…”

Section: Progress In Design Of New Green Catalysts Based On Mxene Mat...mentioning

confidence: 99%

“…The activity of the MAX phase was investigated. [97] Max-derived electrocatalysts were prepared using a two-step in situ electrosynthesis process, namely electrochemical etching and deposition. The first step is the electrochemical etching of the Mo 2 TiAlC 2 MAX phase in a 0.5 M H 2 SO 4 electrolyte.…”

Section: Research Progressmentioning

confidence: 99%

MXene‐based Materials for Water Splitting: Synthesis and Modification

Dong

et al. 2023

Chemistry An Asian Journal

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With abundant metal site and tunable electronic structure, MXene is considered as a promising electrocatalyst for the conversion of energy molecules. In this review, the latest research progress on inexpensive MXene-based catalysts for water electrolysis is summarized. Typical preparation and modification methods and their advantages and disadvantages are briefly discussed, with a focus on the regulation and design of the surface interface electronic states, which improve the electrocatalytic performance of MXene-based materials. The main strategies for the electronic state modification include end-group modification, heteroatom doping, and heterostructure construction. Some limitations of MXene-based materials, which should be considered in the rational design of advanced MXene-based electrocatalyst, are also discussed. Finally, prospects for the rational design of Mxene-based electrocatalysts is proposed.

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In Situ Electrosynthesis of MAX‐Derived Electrocatalysts for Superior Hydrogen Evolution Reaction

Cited by 20 publications

References 50 publications

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

Structural Engineering Enabled Bimetallic (Ti_1‐_yNb_y)₂AlC Solid Solution Structure for Efficient Electromagnetic Wave Absorption in Gigahertz

MXene‐based Materials for Water Splitting: Synthesis and Modification

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In Situ Electrosynthesis of MAX‐Derived Electrocatalysts for Superior Hydrogen Evolution Reaction

Cited by 20 publications

References 50 publications

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

One-Step Electrochemical Synthesis and Surface Reconstruction of NiCoP as an Electrocatalyst for Bifunctional Water Splitting

Structural Engineering Enabled Bimetallic (Ti1‐yNby)2AlC Solid Solution Structure for Efficient Electromagnetic Wave Absorption in Gigahertz

MXene‐based Materials for Water Splitting: Synthesis and Modification

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Structural Engineering Enabled Bimetallic (Ti_1‐_yNb_y)₂AlC Solid Solution Structure for Efficient Electromagnetic Wave Absorption in Gigahertz