Modulating Schottky Barrier of MoS<sub>2</sub> to Enhance Hydrogen Evolution Reaction Activity by Incorporating with Vertical Graphene Nanosheets Derived from Organic Liquid Waste

Wu, Angjian; Xu, Aoni; Yang, Jian; Li, Xiaodong; Wang, Li; Wang, Jingfan; Macdonald, Digby D.; Yan, Jun

doi:10.1002/celc.201801279

Cited by 7 publications

(5 citation statements)

References 38 publications

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“…Interestingly, the rich pyridinic-N in the carbon support provides additional electroactive sites, and there is a positive correlation between HER performance and the content of N dopant. The critical role of the carbon support in enhancing MoS 2 catalysts' HER performance is also identified in the organic liquid waste-derived vertical graphene nanosheets (VGNS)/ MoS 2 hybrid [132]. By combining VGNS with MoS 2 , the Schottky barrier height is reduced from 0.52 to 0.23 eV in the computational model, which is in line with the experimentally reduced overpotential by ∼ 50 mV.…”

Section: Waste-derived Carbon-based Heterostructures For Hersupporting

confidence: 69%

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Chen

Yun

et al. 2022

Nano-Micro Lett.

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The sustainable production of green hydrogen via water electrolysis necessitates cost-effective electrocatalysts. By following the circular economy principle, the utilization of waste-derived catalysts significantly promotes the sustainable development of green hydrogen energy. Currently, diverse waste-derived catalysts have exhibited excellent catalytic performance toward hydrogen evolution reaction (HER), oxygen evolution reaction (OER), and overall water electrolysis (OWE). Herein, we systematically examine recent achievements in waste-derived electrocatalysts for water electrolysis. The general principles of water electrolysis and design principles of efficient electrocatalysts are discussed, followed by the illustration of current strategies for transforming wastes into electrocatalysts. Then, applications of waste-derived catalysts (i.e., carbon-based catalysts, transitional metal-based catalysts, and carbon-based heterostructure catalysts) in HER, OER, and OWE are reviewed successively. An emphasis is put on correlating the catalysts’ structure–performance relationship. Also, challenges and research directions in this booming field are finally highlighted. This review would provide useful insights into the design, synthesis, and applications of waste-derived electrocatalysts, and thus accelerate the development of the circular economy-driven green hydrogen energy scheme.

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Section: Waste-derived Carbon-based Heterostructures For Hersupporting

confidence: 69%

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Chen

Yun

et al. 2022

Nano-Micro Lett.

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“…In summary, we have developed the rGO/SiO 2 composites as an effective and robust HER electrocatalyst via intercalation and pressure sintering. When compared with previously reported graphene‐based structures, such as heteroatom‐doped graphene, [ 14–16 ] edge‐rich vertical graphene, [ 24,42 ] and graphene‐based heterostructures, [ 28,29 ] or composites, [ 32 ] the proposed self‐supported rGO/SiO 2 composites containing abundant rGO edges showed overwhelming advantages regarding the electrocatalytic activity as well as chemical and mechanical stability ( Figure and Table S2, Supporting Information). On the one hand, the preferred orientation and uniform dispersion of the rGO sheets in the SiO 2 matrix resulted in the exposure of electrocatalytic active edges and the improvement of electrical conductivity.…”

Section: Resultsmentioning

confidence: 89%

“…Comparison of the electrocatalytic activity of the rGO/SiO 2 bulk composites with previously reported carbon structures [ 14–16,28,32,42 ] for HER in acidic media.…”

Section: Resultsmentioning

confidence: 99%

Edge‐Rich Reduced Graphene Oxide Embedded in Silica‐Based Laminated Ceramic Composites for Efficient and Robust Electrocatalytic Hydrogen Evolution

Huang

Wang

et al. 2021

Small Methods

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severely restricted their applications. [4] 2D materials, [5] such as metallenes [6] and transition-metal dichalcogenides, [7,8] carbides, [9] and nitrides, [10] have become an irreplaceable choice owing to their large surface area and high electrical conductivity. As the metallic materials suffer from high metal consumption or poor durability, [11] graphene-based metal-free materials, which are earth-abundant resources and have high stability, are potential candidates for electrocatalytic HER. [12] Although perfect graphene is electrochemically inert and often used as a support to load other active nanomaterials, various strategies can be used to adjust its electronic structure and chemical reactivity. [13] For example, the chemical doping of heteroatoms, such as N, S, P, and B, into graphene contributes to high HER activity; [14][15][16][17][18] however, the catalytic mechanism remains controversial. [12] Furthermore, the optimal concentration, proportion, and position of the dopants are difficult to be simultaneously achieved. [19] The topological and edge defects of graphene are important to improve catalytic performance. [20][21][22] Jia et al. first reported a trifunctional graphene catalyst based on the defect mechanism. [23] Due to the abundant structural defects on the edges, the defective graphene exhibited higher electrocatalytic activity than the N-doped graphene. Wei et al. further prepared vertical-oriented N-doped graphene on a glass fiber cloth as a self-support electrode and demonstrated the effects of graphene edge sites on the exceptional HER performance. [24] This method, therefore, is effective in enhancing the HER activity of graphene by creating or exposing more edge sites. Furthermore, more edge sites were exposed in vertical graphene than flat graphene, indicating the importance of graphene orientation. [25] However, the chemical vapor deposition process, commonly used in preparing vertical graphene structures, [26,27] is expensive, complex, and time-consuming. In addition, many graphene-based nanomaterials are in powder form. [28,29] When loading the active materials on the current collector, agglomerations and undesired binders may suppress the electrocatalytic activity and conductivity. [30,31] When the catalysts act as a selfsupported electrode, such as when graphene/ceramic composites are formed, [32] the close contact between the active materials and substrates largely boosts the electrical conductivity To mitigate the energy crisis and environmental pollution, efficient and earth-abundant hydrogen evolution reaction (HER) electrocatalysts are essential for hydrogen production through electrochemical water splitting. Graphene-based materials as metal-free catalysts have attracted significant attention but suffer from insufficient activity and stability. Therefore, a novel and economical approach is developed to prepare highly active, robust, and self-supported reduced graphene oxide (rGO)/SiO 2 ceramic composites as electrocatalysts in HER. Through intercalation and pressure sinteri...

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“…The incorporation of MoS 2 into VGNS led to a dramatically reduced energy gap between the Fermi level and the conduction band minimum (CBM) of MoS 2 , offering prominent HER activity with a reduction of overpotential by 50 mV and a Tafel slope of 38 mV dec −1 . 65 In addition, industrial waste contains large amounts of metals can be used as a metal precursor to form a NiCoMn layered triple hydroxide (LTH) with a hierarchical nanoflower structure by the electrodeposition method. The electrocatalyst exhibited high activity for both OER and HER due to its hierarchical structure and high metal content of 67.33%.…”

Section: Hydrogen Evolution Reaction (Her)mentioning

confidence: 99%

Waste to wealth: direct utilization of spent materials for electrocatalysis and energy storage

Yan

Jiang

et al. 2023

Green Chem.

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Modulating Schottky Barrier of MoS₂ to Enhance Hydrogen Evolution Reaction Activity by Incorporating with Vertical Graphene Nanosheets Derived from Organic Liquid Waste

Cited by 7 publications

References 38 publications

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Edge‐Rich Reduced Graphene Oxide Embedded in Silica‐Based Laminated Ceramic Composites for Efficient and Robust Electrocatalytic Hydrogen Evolution

Waste to wealth: direct utilization of spent materials for electrocatalysis and energy storage

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Modulating Schottky Barrier of MoS2 to Enhance Hydrogen Evolution Reaction Activity by Incorporating with Vertical Graphene Nanosheets Derived from Organic Liquid Waste

Cited by 7 publications

References 38 publications

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Waste-Derived Catalysts for Water Electrolysis: Circular Economy-Driven Sustainable Green Hydrogen Energy

Edge‐Rich Reduced Graphene Oxide Embedded in Silica‐Based Laminated Ceramic Composites for Efficient and Robust Electrocatalytic Hydrogen Evolution

Waste to wealth: direct utilization of spent materials for electrocatalysis and energy storage

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Modulating Schottky Barrier of MoS₂ to Enhance Hydrogen Evolution Reaction Activity by Incorporating with Vertical Graphene Nanosheets Derived from Organic Liquid Waste