Carbon nanotubes anchored onto hollow carbon for efficient oxygen reduction

Sun, Qiuhong; Chen, Dandan; Huang, Qi; Huang, Shaoming; Qian, Jinjie

doi:10.1007/s40843-022-2173-3

Cited by 12 publications

(9 citation statements)

References 48 publications

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“…The structure of the formed ZnS/CoS 2 -C@NC-12 remains after the material undergoes vapor-phase vulcanization. There are still carbon nanotubes on the surface of the core-shell structure (Figure 2a) possibly because the cobalt in the precursor will be used as a kind of catalyst to facilitate the carbon nanotube's growth [11,12,19] under such high carbonization temperature for much longer time than those for ZnS/CoS 2 @C-x. It can be seen from the XRD test results that the characteristic peaks of the ZnS/CoS 2 -C@NC-12 material correspond to the peaks of CoS 2 and ZnS, indicating that the Co and Zn elements in the Zn-Co-ZIF@PDA-12 material are converted into CoS 2 and ZnS (Figure 2c).…”

Section: Resultsmentioning

confidence: 99%

“…However, some MOF-derived composites still suffer from structural instability and insufficient electrical conductivity. To overcome these problems, combining derivatives with conductive carbon materials [19] is an effective strategy. [20,21] In this work, we used bimetallic MOF (Zn-Co-ZIF) as the precursor, coated with dopamine hydrochloride, and prepared ZnS/CoS 2 -C@NC with double-carbon-layer core-shell structure through high-temperature carbonization and gas-phase sulfidation.…”

Section: Introductionmentioning

confidence: 99%

“…However, some MOF‐derived composites still suffer from structural instability and insufficient electrical conductivity. To overcome these problems, combining derivatives with conductive carbon materials [ 19 ] is an effective strategy. [ 20,21 ]…”

Section: Introductionmentioning

confidence: 99%

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Double‐Carbon‐Layer Core–Shell Complex Sulfides Derived from Bimetallic Metal–Organic Frameworks for Li‐/Na‐Ion Battery Storage

Yang

Shen

et al. 2023

Energy Tech

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Metal‐Organic Frameworks (MOFs) have been extensively studied due to their porous structures and large specific surface areas. Its unique combination of central metal and organic ligand has become a common precursor for the synthesis of metal phosphides, selenides, oxides and sulfides. However, the carbonaceous structure derived from some MOF materials is still not enough to perfectly alleviate the negative impact of the volume change of metal sulfides. In this paper, bimetallic MOF (Zn‐Co‐ZIF) was used as a precursor, coated with dopamine hydrochloride and then calcined and gas‐phase vulcanized to prepare ZnS/CoS2‐C@NC with a double carbon layer core‐shell structure. The existence of the two carbonaceous structures can not only improve the electron transport ability, but also play an important role in alleviating the volume expansion caused by metal sulfides during repeated charging and discharging. Due to its stable carbon layer structure, ZnS/CoS2‐C@NC has a higher specific capacity (1175.4 mAh g‐1 in Lithium Ion Batteries(LIBs) and 430.9 mAh g‐1 in Sodium Ion Batteries(SIBs) after 100 cycles at a current density of 0.2 A g‐1 respectively) and excellent rate capability (338.2 mAh g‐1 specific capacity maintained after 2000 cycles at a current density of 5 A g‐1 in LIBs)This article is protected by copyright. All rights reserved.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Double‐Carbon‐Layer Core–Shell Complex Sulfides Derived from Bimetallic Metal–Organic Frameworks for Li‐/Na‐Ion Battery Storage

Yang

Shen

et al. 2023

Energy Tech

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“…[1][2][3] This extensive application can be credited to the distinct characteristics of carbon-based materials DOI: 10.1002/advs.202206960 including good conductivity, favorable chemical and thermal stability, intrinsic hydrophobicity, and easy surface modification. [4][5][6] Among them, hollow carbon materials (HCs) consist of carbon shells and internal cavities, which possess additional features, such as accessible internal cavity, porous carbon shells, high surface area, and adjustable porosity. [7][8][9] In particular, the hollow cavity can offer a high specific surface area together with reduced charge and mass diffusion distance and the mesopores on the shell can provide diffusion channels for rapid ion movement.…”

Section: Introductionmentioning

confidence: 99%

Design of Uniform Hollow Carbon Nanoarchitectures: Different Capacitive Deionization between the Hollow Shell Thickness and Cavity Size

et al. 2023

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Carbon‐based materials with high capacitance ability and fast electrosorption rate are ideal electrode materials in capacitive deionization (CDI). However, traditional carbon materials have structural limitations in electrochemical and desalination performance due to the low capacitance and poor transmission channel of the prepared electrodes. Therefore, reasonable design of electrode material structure is of great importance for achieving excellent CDI properties. Here, uniform hollow carbon materials with different morphologies (hollow carbon nanospheres, hollow carbon nanorods, hollow carbon nano‐pseudoboxes, hollow carbon nano‐ellipsoids, hollow carbon nano‐capsules, and hollow carbon nano‐peanuts) are reasonably designed through multi‐step template method and calcination of polymer precursors. Hollow carbon nanospheres and hollow carbon nano‐pseudoboxes exhibit better capacitance and higher salt adsorption capacity (SAC) due to their stable carbonaceous structure during calcination. Moreover, the effects of the thickness of the shell and the size of the cavity on the CDI performance are also studied. HCNSs‐0.8 with thicker shell (≈20 nm) and larger cavity (≈320 nm) shows the best SAC value of 23.01 mg g−1 due to its large specific surface area (1083.20 m2 g−1) and rich pore size distribution. These uniform hollow carbon nanoarchitectures with functional properties have potential applications in electrochemistry related fields.

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“…The addition of oleic acid enhanced the adsorption of its mixture to the coal surface, but slowed down the diffusion rate, which improved the flotation efficiency [18]. However, all of the above are studied experimentally, and in recent years, with the gradual rise of molecular simulation, it has been widely used in chemistry, physics, materials, and biology [19][20][21][22]. Molecular simulations allow the study of chemical reactions and conformational changes of substances at different spatial scales of micro-, nano-, and mesoscopic scales, which can overcome the problems of insufficient funding for experiments and also enable the dynamic evolution of the simulated system [23][24][25].…”

mentioning

confidence: 99%

Study on the microscopic mechanism of adsorption and diffusion of hydrocarbon oil drops on coal surface using molecular dynamics simulations

Zhao,

Liu

2023

Int J of Quantum Chemistry

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Flotation of fine coal particles usually uses oil collectors, but the micromechanisms need to be more refined due to the complex structure and abundant functional groups on the surface of coal bodies. The adsorption spreading behavior and interfacial properties of nonpolar oil drops on flat low‐order coal (LOC) and high‐order coal (HOC) surfaces were investigated in depth using molecular dynamics (MD) simulations, while the effects of different functional groups on LOC surfaces were also considered. The results showed that the contact angle, contact area and interaction energy of oil drops adsorbed on the LOC and HOC surfaces at simulated equilibrium in aqueous environment were 77.68°, 621.49 Å2, −140.94 kcal/mol; 53.98°, 962.14 Å2, and −195.13 kcal/mol, respectively. The smaller the equilibrium contact angle between the oil drops and the surface, the larger the contact area and the larger the absolute value of the interaction energy, the better the spreading effect of the oil drops and the easier the surface is to flotation. Compared with the HOC surface, the oil drops could not displace the water molecules on the LOC surface better and spread poorly on its surface, and the migration rate was higher. This was caused by the abundant functional groups on the surface of LOC. The type of functional group significantly affects the interaction of nonpolar oil drops with hydrophilic surfaces, with the order of adsorption strength being CH3 > COCH3 > OH > COOH. The formation of a dense hydrated film of oil drops on the COOH surface was an important reason for the difficulty of flotation on the LOC surface. MD elucidated the mechanism of action of nonpolar oil collectors on LOC and HOC surfaces, which is a guide for efficient flotation on LOC surfaces.

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Carbon nanotubes anchored onto hollow carbon for efficient oxygen reduction

Cited by 12 publications

References 48 publications

Double‐Carbon‐Layer Core–Shell Complex Sulfides Derived from Bimetallic Metal–Organic Frameworks for Li‐/Na‐Ion Battery Storage

Double‐Carbon‐Layer Core–Shell Complex Sulfides Derived from Bimetallic Metal–Organic Frameworks for Li‐/Na‐Ion Battery Storage

Design of Uniform Hollow Carbon Nanoarchitectures: Different Capacitive Deionization between the Hollow Shell Thickness and Cavity Size

Study on the microscopic mechanism of adsorption and diffusion of hydrocarbon oil drops on coal surface using molecular dynamics simulations

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