A Robust Ternary Heterostructured Electrocatalyst with Conformal Graphene Chainmail for Expediting Bi‐Directional Sulfur Redox in Li–S Batteries

Cai, Jingsheng; Sun, Zhongti; Cai, Wenlong; Wei, Nan; Fan, Yuxin; Liu, Zhongfan; Zhang, Qiang

doi:10.1002/adfm.202100586

Cited by 84 publications

(54 citation statements)

References 51 publications

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“…The conversion kinetics of as-prepared samples was more obvious in symmetrical cell based on Li 2 S 6 catholyte (Figure 5d). [4] From the CV curves in Figure 5e, except for graphene, the other electrodes showed two distinct redox peaks and high response current, indicating easy conversion between Li 2 S n and Li 2 S 2 /Li 2 S. [47] The redox peak of CoNiO 2 /Co 4 N sample provided the highest intensity and smallest polarization, which was in good agreement with the electrochemical impedance spectroscopy (EIS) results (Figure 5f) for symmetric cells. The charge transfer resistance of symmetrical cell increased in the order of CoNiO 2 /Co 4 N<Co 4 N<CoNiO 2 <graphene, suggesting that the introduction of heterostructure resulted in the obvious improvement in polysulfide conversion kinetics.…”

Section: Resultssupporting

confidence: 79%

CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

Pu¹,

Gong

Shen³

et al. 2021

Advanced Science

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The "shuttle effect" of soluble polysulfides and slow reaction kinetics hinder the practical application of Li-S batteries. Transition metal oxides are promising mediators to alleviate these problems, but the poor electrical conductivity limits their further development. Herein, the homogeneous CoNiO 2 /Co 4 N nanowires have been fabricated and employed as additive of graphene based sulfur cathode. Through optimizing the nitriding degree, the continuous heterostructure interface can be obtained, accompanied by effective adjustment of energy band structure. By combining the strong adsorptive and catalytic properties of CoNiO 2 and electrical conductivity of Co 4 N, the in situ formed CoNiO 2 /Co 4 N heterostructure reveals a synergistic enhancement effect. Theoretical calculation and experimental design show that it can not only significantly inhibit "shuttle effect" through chemisorption and catalytic conversion of polysulfides, but also improve the transport rate of ions and electrons. Thus, the graphene composite sulfur cathode supported by these CoNiO 2 /Co 4 N nanowires exhibits improved sulfur species reaction kinetics. The corresponding cell provides a high rate capacity of 688 mAh g −1 at 4 C with an ultralow decaying rate of ≈0.07% per cycle over 600 cycles. The design of heterostructure nanowires and graphene composite structure provides an advanced strategy for the rapid capture-diffusion-conversion process of polysulfides.

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Section: Resultssupporting

confidence: 79%

CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

Pu¹,

Gong

Shen³

et al. 2021

Advanced Science

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“…[6,7] An electrocatalytic approach to boost sulfur conversion reaction in Li−S chemistry has recently been proposed as an effective strategy to overcome these limitations. [8][9][10][11][12] Transition metal chalcogenides (TMCs) are recognized to be effective sulfur electrocatalysts because of their abundance, environment friendliness, and unique electrochemical properties. [13][14][15][16][17] Among them, metal sulfides arouse particular interest because of their high activity, and thermodynamically stable structures.…”

mentioning

confidence: 99%

Synergetic Anion Vacancies and Dense Heterointerfaces into Bimetal Chalcogenide Nanosheet Arrays for Boosting Electrocatalysis Sulfur Conversion

Jiang

et al. 2022

Advanced Materials

117

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The slow sulfur conversion reactions severely limit the electrochemical performances of Li−S batteries especially under high sulfur loading and lean electrolyte operation. [6,7] An electrocatalytic approach to boost sulfur conversion reaction in Li−S chemistry has recently been proposed as an effective strategy to overcome these limitations. [8][9][10][11][12] Transition metal chalcogenides (TMCs) are recognized to be effective sulfur electrocatalysts because of their abundance, environment friendliness, and unique electrochemical properties. [13][14][15][16][17] Among them, metal sulfides arouse particular interest because of their high activity, and thermodynamically stable structures. [18] However, TMCs are still suffered from insufficient active sites, inferior durability, and weak conductivity. The notable enhancement of catalytic activity for sulfur redox reaction can be achieved by regulating the morphology and internal crystal structure of TMCs. As for morphology control, in situ growing 2D TMC nanosheet arrays with abundant electroactive sites on conductive substrates could provide efficient pathways for electron/ion transport during the sulfur conversion process. [19] Moreover, it was demonstrated that bimetal chalcogenide hetero-catalysts exhibited higher activity than the single-component counterparts. The formed heterointerfaces in bimetal chalcogenide can increase the number of catalytically active sites and provide favorable local coordination and electronic structures. [20,21] For example, the bimetallic chalcogenides, such as ZnS-SnS, [22] MoS 2 /Ni 3 S 2 , [23] and CoSe-ZnSe [24] enable electronic reconfiguration and improve the intrinsic activity for promoting sulfur conversion by the interior built-in electric-field (E-field) induced by phase boundaries. Although promising progress has been made, electrocatalytic activity is still unsatisfactory for a wellfunctioning Li−S battery in terms of boosting the entire sulfur conversion reaction.The introduction of anion vacancies provides another effective strategy to enhance the electrocatalytic activity of TMCs toward boosted Li−S battery upon discharging/charging process. [25][26][27] Electrons in the Se-defect can be excited into the conduction band, producing a low bandgap in the conduction band which is favorable to the sulfur conversion reaction. [28] Moreover, sulfurvacancies (S-vacancies) can regulate the electronic structure of adjacent atoms, thus reducing the decomposition energy barrier Vacancy and interface engineering are regarded as effective strategies to modulate the electronic structure and enhance the activity of metal chalcogenides. However, the practical application of metal chalcogenides in lithium− sulfur (Li−S) batteries is limited by their low conductivity, rapid decline in catalytic activity, and large volume variation during the discharging/charging process. Herein, bimetal sulfide (CoZn-S) nanosheet arrays with sulfur vacancies and dense heterointerfaces are proposed to accelerate sulfur conversion and improve the perform...

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“…5f, which revealed the smallest Tafel slope of 79 mV dec À1 for NiCo-LDH-Se-2, compared with those of NiCo-LDH-Se-0 (248 mV dec À1 ), NiCo-LDH-Se-1 (183 mV dec À1 ), and NiCo-LDH-Se-4 (137 mV dec À1 ), demonstrating its good oxidation ability towards Li 2 S 2 /Li 2 S and LiPSs conversion. 45 Based on these results, the superb SRR performance could be reasonably attributed to the unique electronic structure of the selenided materials with abundant active sites for LiPSs conversion. Additionally, the catalytic effect on the conversion from S 8 to LiPSs was also demonstrated by comparison of the LSV and Tafel plots (Fig.…”

Section: Catalytic Performancementioning

confidence: 72%

NiCo (oxy)selenide electrocatalysts via anionic regulation for high-performance lithium–sulfur batteries

Wang

Sun

et al. 2022

J. Mater. Chem. A

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A Robust Ternary Heterostructured Electrocatalyst with Conformal Graphene Chainmail for Expediting Bi‐Directional Sulfur Redox in Li–S Batteries

Cited by 84 publications

References 51 publications

CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

Synergetic Anion Vacancies and Dense Heterointerfaces into Bimetal Chalcogenide Nanosheet Arrays for Boosting Electrocatalysis Sulfur Conversion

NiCo (oxy)selenide electrocatalysts via anionic regulation for high-performance lithium–sulfur batteries

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A Robust Ternary Heterostructured Electrocatalyst with Conformal Graphene Chainmail for Expediting Bi‐Directional Sulfur Redox in Li–S Batteries

Cited by 84 publications

References 51 publications

CoNiO2/Co4N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

CoNiO2/Co4N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

Synergetic Anion Vacancies and Dense Heterointerfaces into Bimetal Chalcogenide Nanosheet Arrays for Boosting Electrocatalysis Sulfur Conversion

NiCo (oxy)selenide electrocatalysts via anionic regulation for high-performance lithium–sulfur batteries

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CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries

CoNiO₂/Co₄N Heterostructure Nanowires Assisted Polysulfide Reaction Kinetics for Improved Lithium–Sulfur Batteries