Regulating adsorption ability toward polysulfides in a porous carbon/Cu<sub>3</sub>P hybrid for an ultrastable high‐temperature lithium–sulfur battery

Guo, Yichuan; Khatoon, Rabia; Lu, Jianguo; He, Qinggang; Gao, Xiang; Yang, Xiaopeng; Hu, Xun; Yang, Wei; Lian, Jiale; Li, Zhou Peng; Ye, Zhizhen

doi:10.1002/cey2.145

Cited by 53 publications

(21 citation statements)

References 54 publications

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“…[ 27–33 ] Previous research identified that doped heteroatoms (B, N, and P) on carbon hosts could restrict the shuttle effect of polyselenides in Li/Na‐Se batteries with organic electrolytes. [ 34,35 ] However, the effect and mechanism of heteroatom‐doped carbon confining polyselenides were far from full recognition in Zn–Se batteries. Thus, exploring the effect and mechanism of doping heteroatoms (B, N, and P) on carbon hosts in polyselenide adsorption is of paramount importance for Zn–Se batteries with enhanced, long‐lasting performance.…”

Section: Introductionmentioning

confidence: 99%

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Wang

Kang

Long

et al. 2022

Carbon Neutralization

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Zinc–selenium (Zn–Se) batteries have generated great research interest because they could potentially meet the requirements of a high‐capacity, high energy density storage device. Unfortunately, efforts to control the shuttle effect of polyselenides have yielded limited success. Nanostructured carbon hosts with nonpolar surfaces have insufficient ability to restrict polyselenides within the cathode. Herein, first‐principles calculations are used to successfully study the merits of heteroatom‐doped graphene as an efficient sorbent with an excellent ability to inhibit the shuttle effect of polyselenides. The calculation results show that using B as a dopant could distinctly enhance interaction between hosts and polyselenides, which occur significant charge transfer with polyselenides and reduce the diffusion energy barrier of Zn ions. Then, we synthesized carbon/Se and boron‐doped carbon material/Se composite cathodes proving that B‐doped carbon could restrict the shuttle effect of polyselenides, which increases the electrochemical performance of Zn–Se batteries. Therefore, the theoretical study identifies a delightful restricted material that could potentially restrict the shuttle effect in Zn–Se batteries and provides a foundation and strategy for the fabrication of long‐life, high‐power‐density Zn–Se batteries.

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Section: Introductionmentioning

confidence: 99%

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Wang

Kang

Long

et al. 2022

Carbon Neutralization

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“…As a result, the practical application of water electrolysis is severely restricted by the OER process, and highly efficient catalyst materials are desired. [10][11][12] Limited by the high cost and rareness of noble metals, attention has been focused on 3d-transition metal-based non-noble materials like phosphides, [13][14][15] sulfides, 16,17 and selenides. 18 While these catalysts have a delayed reaction in the active phase of high-valence-state metal species formation, increasing the polarity would be useful to overcome the thermodynamic uphill process of O-H bond cleavage and O-O bond formation.…”

mentioning

confidence: 99%

Hetero MOF‐on‐MOF‐derived carbon nanotube interconnected nitrogen‐doped carbon‐encapsulated FeNi/FeF₂ for efficient oxygen evolution reaction

Zhou

Liu

et al. 2022

Carbon Energy

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Heterostructures derived from metal-organic frameworks (MOFs) with multicomponent synergism are significant in the energy conversion and catalysis reactions. Herein, we demonstrated such an efficient catalyst with the structure of self-catalyzed nitrogen-doped carbon nanotube interconnected FeNi/FeF 2 derived from hetero-zeolite imidazolate frameworks 8 (ZIF-8) on Fe 2 Ni MIL (MIL represents Materials of Institut Lavoisier) for oxygen evolution reaction.The obtained catalyst showed efficient synergism of the multicomponents, high polarity, more active sites exposure, increased intrinsic activity, and improved conductivity and stability by a carbon interconnected and confined structure as revealed by the spectroscopic analysis and electrochemical measurements. It required an overpotential of only ca. 240 mV (no iR correction) to reach the current density of 10 mA cm −2 in a KOH solution when loaded on an inert glass carbon electrode, much better than similar kinds of catalysts. The improved catalytic performance can be well correlated to the structural transformation step by step from different MOFs to their derivatives by subsequent carbonation and fluorination. Because of the above-mentioned structural advantages, good catalysis performance of high activity and stability, faster catalytic kinetics, and facile active phase formation were observed compared to those of other similar materials. This work offers a new platform of derivatives from hetero MOF-on-MOF for catalysis reactions.

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“…Recently, a large amount of efforts have been made to synthesize new separator modifying materials, such as heteroatom-doped carbon materials, , metal carbides, metal oxides, spinels, and perovskites, which can interact strongly with polysulfides. Transition-metal phosphides, such as Ni 2 P, FeP, Cu 3 P, and NiCoP, have attracted academic attention due to their good electrochemical stability, low charge–discharge polarization voltage, and strong polarity. It has been reported that Ni 2 P is a very promising material due to low decomposition energy barriers of Li 2 S and strong interactions with polysulfides .…”

Section: Introductionmentioning

confidence: 99%

Synthesis of the Ni₂P–Co Mott–Schottky Junction as an Electrocatalyst to Boost Sulfur Conversion Kinetics and Application in Separator Modification in Li-S Batteries

Zhang

Qiao

et al. 2023

ACS Appl. Mater. Interfaces

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To overcome the shuttling effect and sluggish conversion kinetics of polysulfides, a large number of catalysts have been designed for lithium−sulfur (Li−S) batteries. Herein, a Mott−Schottky junction catalyst composed of Co nanoparticles and Ni 2 P was designed to improve polysulfide kinetics. Our investigations reveal the rearrangement of charges at the Schottky junction interface and the construction of the built-in electric field are crucial for lowering the activation energy of the dissolved Li 2 S n reduction and Li 2 S nucleation reaction. Furthermore, a series of experimental and electrochemical tests were performed to demonstrate that the Schottky catalytic effect enhanced the synergistic catalytic effect. With a Ni 2 P−Co@CNT catalyst, the battery exhibits an initial specific capacity of 874 mAh g −1 at a rate of 4.0 C, and the decay rate per cycle is 0.049% in 700 cycles. Meanwhile, the battery shows 0.118% decay rate per cycle at 0.5 C in 100 cycles at a high sulfur loading of 10 mg cm −2 . The Schottky heterojunction structure proposed here has been shown to have a good catalytic effect on the reduction of Li 2 S n and nucleation of Li 2 S, which provides a profound guidance for efficient and rational catalyst design.

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Regulating adsorption ability toward polysulfides in a porous carbon/Cu₃P hybrid for an ultrastable high‐temperature lithium–sulfur battery

Cited by 53 publications

References 54 publications

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Hetero MOF‐on‐MOF‐derived carbon nanotube interconnected nitrogen‐doped carbon‐encapsulated FeNi/FeF₂ for efficient oxygen evolution reaction

Synthesis of the Ni₂P–Co Mott–Schottky Junction as an Electrocatalyst to Boost Sulfur Conversion Kinetics and Application in Separator Modification in Li-S Batteries

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Regulating adsorption ability toward polysulfides in a porous carbon/Cu3P hybrid for an ultrastable high‐temperature lithium–sulfur battery

Cited by 53 publications

References 54 publications

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Hetero MOF‐on‐MOF‐derived carbon nanotube interconnected nitrogen‐doped carbon‐encapsulated FeNi/FeF2 for efficient oxygen evolution reaction

Synthesis of the Ni2P–Co Mott–Schottky Junction as an Electrocatalyst to Boost Sulfur Conversion Kinetics and Application in Separator Modification in Li-S Batteries

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Regulating adsorption ability toward polysulfides in a porous carbon/Cu₃P hybrid for an ultrastable high‐temperature lithium–sulfur battery

Hetero MOF‐on‐MOF‐derived carbon nanotube interconnected nitrogen‐doped carbon‐encapsulated FeNi/FeF₂ for efficient oxygen evolution reaction

Synthesis of the Ni₂P–Co Mott–Schottky Junction as an Electrocatalyst to Boost Sulfur Conversion Kinetics and Application in Separator Modification in Li-S Batteries