Amorphous Fe–Ni–P–B–O Nanocages as Efficient Electrocatalysts for Oxygen Evolution Reaction

Ren, Hao; Sun, Xiaoli; Du, Chunyu; Zhao, Jianwei; Liu, Daobin; Fang, Wei; Kumar, Sonal; Chua, Rodney; Meng, Shize; Kidkhunthod, Pinit; Li, Song; Li, Shuiqing; Srinivasan, Madhavi; Yan, Qingyu

doi:10.1021/acsnano.9b05571

Cited by 154 publications

(102 citation statements)

References 70 publications

(146 reference statements)

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“…To prepare the low cyrstalline and ultra‐thin R‐Ni 10−x Fe x ‐CP nanosheets, NaBH 4 was chosen as a reductant to produce structural deficiencies and distortions (see Experimental details in the Supporting Information). [ 19,23,31–33 ] The PXRD patterns (Figure S7, Supporting Information) of R‐Ni 10−x Fe x ‐CPs (0 ≤ x ≤ 5) showed low crystallinity with main diffraction peaks at 2θ ≈ 15.5° and 26.8°, which correspond to the (012) and (110) planes of a Ni(OH) 2 ·0.75H 2 O reference (JCPDS No. 38–0715), respectively.…”

Section: Resultsmentioning

confidence: 99%

“…Notably, no B signal was detected from the XPS B1s spectra of R‐NiFe‐CPs (Figure S36, Supporting Information), which is further implying that R‐NiFe‐CPs emerged from the proposed reaction mechanism (see Experimental details in the Supporting Information, Tables S2 and S4, Supporting Information). [ 19,23 ] Noteworthy, the binding energy of Ni 2p in R‐NiFe‐CPs exhibited a negative shift around 0.91 eV compared with that of NiFe‐LDH (Figure 3d). For the XPS spectrum of O 2s in NiFe‐LDH (Figure 3e), three main peaks located at 529.68, 531,39, and 532.98 eV, respectively, are assigned to metal‐oxygen bonds, surface hydroxyl groups, and adsorbed water.…”

Section: Resultsmentioning

confidence: 99%

“…Ni‐CPs and R‐Ni‐CPs were employed as reference catalysts here, because the substitution of Fe may either promote or diminish the OER activity, depending on the Fe content. [ 23,37,65–67 ] Therefore, the effects of varying the Ni/Fe atomic ratio on the OER performance were first investigated (Figure S38, Supporting Information). A 90% iR‐correction was performed to evaluate all cyclic voltammetry (CV) measurements (Figure S39, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…As presented in Figure S38, Supporting Information, the OER activities of the catalyst series exhibited a significant volcano trend as a function of the atomic ratio of Ni/Fe, which is consistent with previous studies on NiFe‐based catalysts. [ 23,37,65–67 ] The best OER performance was observed in the samples with 20% Fe substitution, referred to herein as R‐NiFe‐CPs (see Section 2.2.). After optimizing the mass loading of as‐prepared catalysts, the electrodes with 0.4 mg cm −2 exhibited the best OER activity (Figure S40, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…Moreover, CPA‐ or CP‐derived compounds have recently emerged as new competitive candidates compared to many of the state‐of‐the‐art transition metal‐based electrocatalysts. [ 19–24 ] Despite these tremendous achievements on CPAs and CPs, their straightforward construction as efficient transition metal‐based electrocatalysts still remains a challenge.…”

Section: Introductionmentioning

confidence: 99%

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Understanding and Optimizing Ultra‐Thin Coordination Polymer Derivatives with High Oxygen Evolution Performance

Zhao

Wan

Chen

et al. 2020

Advanced Energy Materials

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fuel shortage and climate change. [1] Noble metal-based materials (e.g., Pt and its alloys) have been well investigated and are among the most promising electrocatalysts for water splitting to generate clean hydrogen. [2,3] However, Pt group-based catalysts are still constrained by their scarcity and high cost for scalable and commercial electrocatalysis. Hence, the development of noble-metal-free catalysts with comparable catalytic activity and robust durability is an urgent task to realize technical applications of water electrolysis. [4,5] Coordination polymer assemblies (CPAs), which are composed of a metal center linked to organic or inorganic ligands combine tunable porous structures, well-dispersed metal sites, high surface areas, and good chemical stability. This renders them excellent materials for drug delivery, [6] gas storage and separation, [7] batteries, [8,9] and catalysis. [10-13] Thanks to their unique structural properties, transition metal-based CPAs keep attracting broad interest in the field of heterogeneous electrocatalysts. [9a,b-14] However, their intrinsic poor conductivity, low mass permeability, and confined active metal centers need to be systematically improved for their application as efficient electrocatalysts. Moreover, instability issues of the ligands such as self-oxidation or degradation at high oxidation potentials need to be resolved for directly using CPAs as long-term electrocatalysts. [14-17] Several strategies, for example, morphological modulation, electronic tuning, and surface modification, have been confirmed as promising approaches to improve the electrocatalytic performance of CPAs and CPs. [14,16-21] In a representative study, ultra-thin NiCo bimetallic CPA nanosheets with enhanced OER activity compared to bulk NiCo bimetallic CPAs, were synthesized through an ultrasonication exfoliation method. [14] Zhang et al. [16] demonstrated that monolayered heterogenous nanosheets of hybrid CoFeO x /CPAs were promising OER electrocatalysts. Some of us recently [20] proposed that the high and durable electrocatalytic activity of a new 1D cobalt coordination polymer (Co-dppeO 2) is due to its highly disordered structure, giving rise to exceptional resilience. Further theoretical calculations and in situ characterizations proved that the key architecture behind the high OER activity was arising from the {H 2 O-Co 2 (OH) 2-OH 2 } edge-site motifs. This study demonstrated the high potential of low-cost Engineering low-crystalline and ultra-thin nanostructures into coordination polymer assemblies is a promising strategy to design efficient electrocatalysts for energy conversion and storage. However, the rational utilization of coordination polymers (CPs) or their derivatives as electrocatalysts has been hindered by a lack of insight into their underlying catalytic mechanisms. Herein, a convenient approach is presented where a series of Ni 10-x Fe x-CPs (0 ≤ x ≤ 5) is first synthesized, followed by the introduction of abundant structural deficiencies using a facile reductive method ...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Understanding and Optimizing Ultra‐Thin Coordination Polymer Derivatives with High Oxygen Evolution Performance

Zhao

Wan

Chen

et al. 2020

Advanced Energy Materials

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Stabilization, Characterization, and Electrochemical Applications of High‐Entropy Oxides: Critical Assessment of Crystal Phase–Properties Relationship

Tomboc

Zhang

Choi

et al. 2022

Adv Funct Materials

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High-entropy oxides (HEOs), a class of newly emerging energy conversion and storage technology materials, have gained significant interest due to their unique structure, complex stoichiometry, and corresponding synergetic effect. Despite the increasing number of reported studies related to HEOs in recent years, details of their structural properties and electrochemical activities are still lacking. Herein, the exciting developments of HEOs regarding their design, synthesis, characterization, theoretical calculations, and electrochemical performances are outlined. The fundamentals of HEOs, including their strict definition, main features, and four-core aspect effects are presented. The different synthetic methods of HEOs are categorized to highlight the significance of parameter optimization to ensure the single-phase stability of HEOs. The advances in characterization techniques on the local lattice and atomic distribution and the basic principles of combinatorial screening methods based on computational techniques are also elaborated. Recent HEO-based electrode/electrocatalysts toward Li-ion batteries and oxygen catalysis are reviewed to assess the potential applications of HEOs. This review draws attention to the critical challenges of HEOs that are worth more extensive explorations in the future.

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Comprehensive Understandings into Complete Reconstruction of Precatalysts: Synthesis, Applications, and Characterizations

et al. 2021

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Reconstruction induced by external environment (such as applied voltage bias and test electrolytes) changes catalyst component and catalytic behaviors. Investigations of complete reconstruction in energy conversion recently receive intensive attention, which promote the targeted design of top‐performance materials with maximum component utilization and good stability. However, the advantages of complete reconstruction, its design strategies, and extensive applications have not achieved the profound understandings and summaries it deserves. Here, this review systematically summarizes several important advances in complete reconstruction for the first time, which includes 1) fundamental understandings of complete reconstruction, the characteristics and advantages of completely reconstructed catalysts, and their design principles, 2) types of reconstruction‐involved precatalysts for oxygen evolution reaction catalysis in wide pH solution, and origins of limited reconstruction degree as well as design strategies/principles toward complete reconstruction, 3) complete reconstruction for novel material synthesis and other electrocatalysis fields, and 4) advanced in situ/operando or multiangle/level characterization techniques to capture the dynamic reconstruction processes and real catalytic contributors. Finally, the existing major challenges and unexplored/unsolved issues on studying the reconstruction chemistry are summarized, and an outlook for the further development of complete reconstruction is briefly proposed. This review will arouse the attention on complete reconstruction materials and their applications in diverse fields.

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Amorphous Fe–Ni–P–B–O Nanocages as Efficient Electrocatalysts for Oxygen Evolution Reaction

Cited by 154 publications

References 70 publications

Understanding and Optimizing Ultra‐Thin Coordination Polymer Derivatives with High Oxygen Evolution Performance

Understanding and Optimizing Ultra‐Thin Coordination Polymer Derivatives with High Oxygen Evolution Performance

Stabilization, Characterization, and Electrochemical Applications of High‐Entropy Oxides: Critical Assessment of Crystal Phase–Properties Relationship

Comprehensive Understandings into Complete Reconstruction of Precatalysts: Synthesis, Applications, and Characterizations

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