11 results on '"He, Chuanxin"'
Search Results
2. Unlocking the Transition of Electrochemical Water Oxidation Mechanism Induced by Heteroatom Doping.
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Li, Xuan, Deng, Chen, Kong, Yan, Huo, Qihua, Mi, Lingren, Sun, Jianju, Cao, Jianyong, Shao, Jiaxin, Chen, Xinbao, Zhou, Weiliang, Lv, Miaoyuan, Chai, Xiaoyan, Yang, Hengpan, Hu, Qi, and He, Chuanxin
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HYDROGEN evolution reactions ,OXIDATION of water ,OXYGEN evolution reactions ,ELECTROCATALYSTS ,ADSORBATES ,BINDING energy - Abstract
Heteroatom doping has emerged as a highly effective strategy to enhance the activity of metal‐based electrocatalysts toward the oxygen evolution reaction (OER). It is widely accepted that the doping does not switch the OER mechanism from the adsorbate evolution mechanism (AEM) to the lattice‐oxygen‐mediated mechanism (LOM), and the enhanced activity is attributed to the optimized binding energies toward oxygen intermediates. However, this seems inconsistent with the fact that the overpotential of doped OER electrocatalysts (<300 mV) is considerably smaller than the limit of AEM (>370 mV). To determine the origin of this inconsistency, we select phosphorus (P)‐doped nickel‐iron mixed oxides as the model electrocatalysts and observe that the doping enhances the covalency of the metal‐oxygen bonds to drive the OER pathway transition from the AEM to the LOM, thereby breaking the adsorption linear relation between *OH and *OOH in the AEM. Consequently, the obtained P‐doped oxides display a small overpotential of 237 mV at 10 mA cm−2. Beyond P, the similar pathway transition is also observed on the sulfur doping. These findings offer new insights into the substantially enhanced OER activity originating from heteroatom doping. [ABSTRACT FROM AUTHOR]
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- 2023
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3. Cation Defect Engineering of Transition Metal Electrocatalysts for Oxygen Evolution Reaction.
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Yan, Dafeng, Xia, Chenfeng, Zhang, Wenjing, Hu, Qi, He, Chuanxin, Xia, Bao Yu, and Wang, Shuangyin
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OXYGEN evolution reactions ,CATIONS ,ENGINEERING drawings ,SURFACE reconstruction ,ELECTRONIC structure ,ELECTROCATALYSTS ,HYDROGEN evolution reactions - Abstract
The rational design and development of highly efficient oxygen evolution reaction (OER) electrocatalysts is vital for the application of renewable energy devices. Recently, the strategy of defect engineering draws much attention due to its positive effect on regulating the electronic structure, and thus, promoting the electrocatalytic performance of various materials. In this review, the main focus is on the cation vacancy defects of transition metal‐based electrocatalysts; the latest progress in cation vacancy defect engineering for the electrocatalytic OER is summarized. The different effects of cation vacancy defects on OER are well discussed together with the reaction mechanism, mainly including improving the conductivity, optimizing the adsorption of key intermediates, guiding the surface reconstruction to form active species, and enhancing the long‐term stability. Then, methods to construct cation vacancy defects on different electrocatalysts and the characterization of cation vacancies are systematically introduced. Finally, the remaining challenges and future prospects of cation vacancy defect engineering for promoting OER performance are further proposed. [ABSTRACT FROM AUTHOR]
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- 2022
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4. Superhydrophilic Phytic‐Acid‐Doped Conductive Hydrogels as Metal‐Free and Binder‐Free Electrocatalysts for Efficient Water Oxidation.
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Hu, Qi, Li, Guomin, Liu, Xiufang, Zhu, Bin, Chai, Xiaoyan, Zhang, Qianling, Liu, Jianhong, and He, Chuanxin
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ELECTROCATALYSTS ,OXYGEN evolution reactions ,OXIDATION of water ,PHYTIC acid - Abstract
Recently, metal‐free, heteroatom‐doped carbon nanomaterials have emerged as promising electrocatalysts for the oxygen evolution reaction (OER), but their synthesis is a tedious process involving energy‐wasting calcination. Molecular electrocatalysts offer attractive catalysts for the OER. Here, phytic acid (PA) was selected to investigate the OER activity of carbons in organic molecules by DFT calculations and experiments. Positively charged carbons on PA were very active towards the OER. The PA molecules were fixed into a porous, conductive hydrogel with a superhydrophilic surface. This outperformed most metal‐free electrocatalysts. Besides the active sites on PA, the high OER activity was also related to the porous and conductive networks on the hydrogel, which allowed fast charge and mass transport during the OER. Therefore, this work provides a metal‐free, organic‐molecule‐based electrocatalyst to replace carbon nanomaterials for efficient OER. Positively charged carbons on organic molecules (i.e. phytic acid, denoted PA) can participate in the oxygen evolution reaction (OER), as shown by DFT calculations and experiments. Moreover, doping of PA into a porous and conductive hydrogel is a robust strategy for stabilizing PA, as well as boosting the charge and mass transport of PA during the OER. [ABSTRACT FROM AUTHOR]
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- 2019
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5. Crafting MoC2-doped bimetallic alloy nanoparticles encapsulated within N-doped graphene as roust bifunctional electrocatalysts for overall water splitting.
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Hu, Qi, Liu, Xiufang, Zhu, Bin, Fan, Liangdong, Chai, Xiaoyan, Zhang, Qianling, Liu, Jianhong, He, Chuanxin, and Lin, Zhiqun
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Despite recent vigorous progress in synthesis of monofunctional electrocatalysts for hydrogen evolution reaction (HER) or oxygen evolution reaction (OER), it remains challenging to develop bifunctional electrocatalysts for efficient overall water splitting. Herein, we report the crafting of MoC 2 -doped NiFe alloy nanoparticles (NPs) encapsulated within a-few-layer-thick N-doped graphene (denoted NG-NiFe@MoC 2 ) via one-step calcination of hybrid precursors containing polymer-encapsulating binary Prussian blue analogues NPs and Mo 6+ cations. The resulting NG-NiFe@MoC 2 nanohybrids were exploited as electrocatalysts and exhibited excellent performance on either HER or OER separately as a direct consequence of the synergistic effects of unique compositions (i.e., MoC 2 dopants and NiFe alloy NPs; both exerted profound influence on HER and OER) and advantageous architecture (i.e., a-few-layer-thick N-doped graphene encapsulating shell). Remarkably, an alkaline electrolyte capitalizing on NG-NiFe@MoC 2 nanohybrids as bifunctional electrocatalysts achieved overall water-splitting (i.e., concurrent HER and OER) current density of 10 mA cm −2 at a low potential of 1.53 V over a period of 10-h operation, outperforming the precious Pt/C//RuO 2 counterpart. [ABSTRACT FROM AUTHOR]
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- 2018
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6. Redox route to ultrathin metal sulfides nanosheet arrays-anchored MnO2 nanoparticles as self-supported electrocatalysts for efficient water splitting.
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Hu, Qi, Liu, Xiufang, Zhu, Bin, Li, Guomin, Fan, Liangdong, Chai, Xiaoyan, Zhang, Qianling, Liu, Jianhong, and He, Chuanxin
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METAL sulfides , *MANGANESE dioxide , *HYDROGEN production , *METAL nanoparticles , *ELECTROCATALYSTS , *ELECTROLYSIS - Abstract
The efficient and sustainable production of high-purity hydrogen gas through electrochemical water splitting calls for robust and bifunctional catalysts to accelerate the two half reactions of water splitting. Herein, we in-situ craft ultrathin CoNi-sulfides nanosheet (∼2.2 nm in thickness) arrays-anchored MnO 2 nanoparticles (∼3.2 nm in diameter) (denoted U-CoNi-S-NSA/MnO 2 ) via a spontaneous redox process between CoNi-sulfides nanosheet and MnO 4 − anions at ambient temperature. The hierarchical U-CoNi-S-NSA/MnO 2 nanocomposites are then directly employed as self-supported catalysts for the two half reactions of water splitting, showing excellent activity with small overpotentials of 170 mV for oxygen evolution reaction and 67 mV for hydrogen evolution reaction to achieve 10 mA cm −2 , respectively. Moreover, an efficient water electrolyzer through using U-CoNi-S-NSA/MnO 2 as both anodic and cathodic catalysts is fabricated, which achieves current density of 10 mA cm -2 at a small voltage of 1.51 V over a long-time operation of 20 h. This outstanding performance is markedly superior than that of precious Pt/C//RuO 2 counterpart (1.61 V). Therefore, the as-synthesized hierarchical nanocomposites are promising candidates for cheap and efficient water splitting. [ABSTRACT FROM AUTHOR]
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- 2018
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7. High efficiency oxygen evolution reaction enabled by 3D network composed of nitrogen-doped graphitic carbon-coated metal/metal oxide heterojunctions.
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Hu, Qi, Liu, Xiufang, Tang, Chaoyun, Fan, Liangdong, Chai, Xiaoyan, Zhang, Qianling, Liu, Jianhong, and He, Chuanxin
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METALLIC oxides , *METAL coating , *HETEROJUNCTIONS , *OXYGEN evolution reactions , *ELECTROCATALYSTS , *ALTERNATIVE fuels - Abstract
The ability to develop low-cost highly efficient electrocatalyst for oxygen evolution reaction (OER) is key to the overall water splitting device that represents a viable and promising source of alternative energy. Herein, we crafted three-dimensional (3D) network comprising nitrogen-doped graphitic carbon-coated heterojunctions (denoted NC-Ni 0.36 Fe 0.64 /MnO x ) via one-step calcination of hybrid precursors containing ternary Prussian blue analogues and polymers. The NC-Ni 0.36 Fe 0.64 /MnO x nanocomposites were then exploited as catalysts for OER, displaying exceptional performance with a small overpotential of 300 mV to reach 10 mA cm −2 , a low Tafel slope of 43 mV/dec and an outstanding stability without deactivation over a 10-h OER. Notably, compared to commercial RuO 2 catalysts, NC Ni 0.36 Fe 0.64 /MnO x catalysts demonstrated much lower overpotential and Tafel slope. The excellent OER performance can be attributed to the presence of high-valence oxidized metal species (Ni 2+ , Fe 2+ and Mn 2+ ) at the heterostructured interface as well as pyridinic N-doped carbon species on highly conductive graphitic carbon network, thus greatly facilitating the electron-withdrawing from OH − and thus charge transfer during OER. This simple yet effective strategy may open new possibilities for creating a wide range of low-cost, high-efficiency, non-precious transition metal OER catalysts for the overall water splitting. [ABSTRACT FROM AUTHOR]
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- 2018
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8. N, S heteroatom co-doped carbon-based materials carrying Mn and Co atoms as bifunctional catalysts for stable rechargeable zinc-air batteries.
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Li, Xianliang, Zhou, Tingyi, Luo, Zhaoyan, Zhang, Lei, Ren, Zhiheng, Zhang, Qianling, He, Chuanxin, Jiang, Xiantao, Li, Yongliang, and Ren, Xiangzhong
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CARBON-based materials , *OXYGEN reduction , *HYDROGEN evolution reactions , *OXYGEN evolution reactions , *STORAGE batteries , *DOPING agents (Chemistry) , *ATOMS , *CATALYSTS - Abstract
Rational designing of efficient bifunctional oxygen electrocatalysts is significantly important but rather challenging for rechargeable zinc-air batteries. Herein, a novel high-performance bifunctional oxygen electrocatalyst for rechargeable zinc–air batteries are constructed based on bimetal Mn@Co-N-C encapsulated in in situ grown N,S-doped graphitic carbon framework with within a porous three-dimensional (3D) structure. The final catalyst shows a high half-wave potential of 0.89 V for oxygen reduction reaction, and a low operating overpotential of 0.38 V to achieve a 10 mA cm−2 current density for oxygen evolution reaction. The physical characterizations reveal that a strong synergetic coupling between bimetal Mn@Co-N-C and S dopant can effectively increase the active sites, meanwhile achieve a rational manipulation of the active site configuration toward a favorable electronic structure. Impressively, the assembled zinc–air batteries using liquid electrolytes and the all-solid-state batteries with this catalyst exhibit excellent charging–discharging performance, long lifetime, and high flexibility. [Display omitted] • The second metal source is Mn, which utilizes a controlled self-assembly method to orient on N, S-doped carbon-based materials generated from MOFs. • The synthesized Mn@Co-NS catalyst exhibits excellent bifunctional electrocatalytic activity. • The reasons for the superior performance of Mn@CO-NS catalysts are revealed. • Mn@Co-NS has good performance and long-term stability in the field of zinc-air batteries. • It provides direction guidance for the qualitative landing of various metals on carbon substrates, bringing the application of zinc-air batteries to a new level. [ABSTRACT FROM AUTHOR]
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- 2023
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9. The construction of stable Ru/RuO2 porous reticular heterostructure with highly efficient electrocatalytic activity for oxygen evolution reaction.
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Hu, Jing, Fu, Yonghuan, Yang, Penggang, Guo, Licheng, Ye, Shenghua, Ren, Xiangzhong, He, Chuanxin, Zhang, Qianling, and Liu, Jianhong
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OXYGEN evolution reactions , *HYDROGEN evolution reactions , *ANODIC oxidation of metals , *ALKALINE solutions , *CALCINATION (Heat treatment) , *NANOPARTICLES , *SULFURIC acid , *SURFACE area - Abstract
A facile construction of Ru/RuO 2 composite with porous reticular structure (denoted as Ru/RuO 2 -PRS) by controllable pyrolysis of Ru3+ coordinated cyanoguanidine was presented for oxygen evolution reaction (OER). The Ru/RuO 2 heterostructure was identified in Ru/RuO 2 -PRS. Taking the advantages of the Ru/RuO 2 heterostructure and large specific surface area, Ru/RuO 2 -PRS exhibits much more improved OER activity with much lower onset potential and overpotential to reach the current density of 10 mA cm−2 compared with RuO 2 porous powder and RuO 2 nano-particles counterparts in both acidic and alkaline solution. Specifically, Ru/RuO 2 -PRS exhibits much improved durability because the unique Ru/RuO 2 heterostructure relieves the dissolution of RuO 2 at high anodic potential that has been the bottleneck of Ru-based catalysts for OER, especially in acidic electrolyte. This study provides a new strategy to promote the OER application in acidic solution. • We present a facile one-step calcination method to synthesize 3D porous reticular structure of Ru/RuO 2 (Ru/RuO 2 -PRS). • The as prepared Ru/RuO 2 -PRS presents abundant Ru/RuO 2 heterostructure, which benefits to the electrocatalytic process. • Ru/RuO 2 -PRS exhibits excellent OER activity and stability in both acid and alkaline electrolyte. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
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10. Integrating well-controlled core-shell structures into "superaerophobic" electrodes for water oxidation at large current densities.
- Author
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Hu, Qi, Wang, Ziyu, Huang, Xiaowan, Qin, Yongjie, Yang, Hengpan, Ren, Xiangzhong, Zhang, Qianling, Liu, Jianhong, Shao, Minhua, and He, Chuanxin
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OXIDATION of water , *DENSITY currents , *KARST , *OXYGEN evolution reactions , *ELECTRODES , *HYDROGEN evolution reactions - Abstract
• A nature-inspired etching strategy is developed for the construction of karst topography (KT)-featured electrode. • The KT architecture offers a "superaerophobic" surface for rapidly releasing O 2 bubbles during electrocatalysis. • Experimentally identifying that the core-shell structure optimizes the adsorption strength of *OH intermediates. • The obtained electrocatalysts achieve the large current densities of 1500 mA cm−2 at an overpotential of 380 mV. Exploring of electrocatalysts for high-output oxygen evolution reaction (OER) is key to practical applications, but still remains challenging. Here, we developed a nature-inspired etching strategy for the construction of karst topography (KT)-featured electrode comprising core-shell structured Ni(0)@Ni(II) towards efficient OER. Intriguingly, the KT architecture confers a "superaerophobic" surface to render the large amount of generated O 2 bubbles release rapidly and timely from the electrode surface at the high current density of OER (i.e., 1500 mA cm−2). Moreover, this strategy allows good control over the generated core-shell structure for promoting the heterointerface synergetic effect of Ni(0)@Ni(II). By adding probing molecules to react with OER intermediates under operation conditions, we obtain first direct experimental evidence that the core-shell structure can optimize the adsorption strength of *OH for significantly boosting the OER kinetics. Notably, the obtained electrode has excellent performance for OER with a small overpotenital of 380 mV at 1500 mA cm−2. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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11. Engineering defect-rich Fe-doped NiO coupled Ni cluster nanotube arrays with excellent oxygen evolution activity.
- Author
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Lei, Yaqi, Xu, Tingting, Ye, Shenghua, Zheng, Lirong, Liao, Peng, Xiong, Wei, Hu, Jing, Wang, Yajie, Wang, Jingpeng, Ren, Xiangzhong, He, Chuanxin, Zhang, Qianling, Liu, Jianhong, and Sun, Xueliang
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HYDROGEN evolution reactions , *NANOTUBES , *TRANSITION metal oxides , *OXYGEN evolution reactions , *X-ray absorption , *CATALYTIC activity , *CARBON fibers - Abstract
A novel structure of Fe-doped NiO coupled Ni cluster hollow nanotube arrays (Fe-NiO-Ni CHNAs) composed of defect-rich NiO phase and Ni clusters anchored on outside of nanotubes is presented. The d-band downshifted by Fe-doping, coupled of Ni clusters and defect-rich nature greatly improve electrocatalytic performances of Fe-NiO-Ni CHNAs toward oxygen evolution reaction. • A multi-level structure of Fe-doped NiO coupled Ni cluster hollow nanotube arrays (Fe-NiO-Ni CHNAs) was synthesized as a catalyst for OER. • Fe-NiO-Ni CHNAs exhibits overpotential of 245 mV at 10 mA cm−2 and outstanding durability that surpasses most of transition metal oxides. • The improved OER activity is mainly because Fe doping downshifts the d-band of metal sites. • Fe-NiO-Ni CHNAs obeyed the adsorbate evolution mechanism with a nonconcerted proton-electron transfer pathway. Herein we present a novel multi-level structure of Fe-doped NiO coupled Ni cluster hollow nanotube arrays (Fe-NiO-Ni CHNAs) grown on carbon fiber cloth as an efficient catalyst for oxygen evolution reaction. In this multi-level structure, rocksalt-type Fe-doped NiO phase hybrids with Ni clusters coupled into the nanospheres anchored to the outside of nanotube, forming a unique 3D corn-like structure. This novel multi-level structure represents a large specific area for catalytic reaction. X-ray absorption fine structure indicates that the defect-rich Fe-doped NiO phase has abundant coordinative unsaturated sites as active sites, and Fe doping downshifts the d-band of metal sites, which is the main contribution to the improved oxygen evolution reaction catalytic activity. The OER of Fe-NiO-Ni CHNAs obeys the adsorbate evolution mechanism with the nonconcerted proton-electron transfer pathway as a rate-determining step. Thus Fe-doped NiO CHNAs exhibits excellent OER performance and outstanding durability that surpasses most of transition metal oxides. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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