Biometabolically Derived Selenium Nanoparticles Armed with Protein Protective Suit toward High‐Performance Li‐Se Batteries

Xia, Yang; Lu, Chengwei; Fan, Wenluxi; Fang, Ruyi; Xu, Lusheng; Huang, Haichan; Xiao, Zhen; Zhang, Jun; Huang, Hui; Gan, Yongping; He, Xinping; Tao, Xinyong; Xia, Xinhui; Zhang, Wenkui

doi:10.1002/adma.202406894

Advanced Materials

2024

DOI: 10.1002/adma.202406894

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Biometabolically Derived Selenium Nanoparticles Armed with Protein Protective Suit toward High‐Performance Li‐Se Batteries

Yang Xia,

Chengwei Lu,

Wenluxi Fan

et al.

Abstract: Selenium (Se) serves as a burgeoning high‐energy‐density cathode material in lithium‐ion batteries. However, the development of Se cathode is strictly limited by low Se utilization and inferior cycling stability arising from intrinsic volume expansion and notorious shuttle effect. Herein, a microbial metabolism strategy is developed to prepare “functional vesicle‐like” Se globules via Bacillus subtilis subsp. from selenite in sewage, in which Se nanoparticles are armed with a natural biological protein membran… Show more

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Cited by 3 publications

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Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Luo,

Yang,

Gai

et al. 2024

Angewandte Chemie

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High‐capacity electrodes face a great challenge of cycling stability due to particle fragmentation induced conductive network failure and accompanied by sustained electrolyte decomposition for repeatedly build solid electrolyte interphase (SEI). Herein, Se‐solubility induced Sex2‐ as self‐adjustment electrolyte additive to regulate electric double layer (EDL) for constructing novel triple‐layer SEI (inner layer: Se; medium layer: inorganic; outer layer: organic) on high‐capacity FeS2 anode as an example for achieving stable and fast sodium storage. In detail, Sex2‐ in‐situ generated at 1.30 V (vs. Na+/Na) and was preferentially adsorbed onto EDL of anode, then converted to Se0 as inner layer of SEI. In addition, the Sex2‐ causes anion‐enhanced Na+ solvation structure could produce more inorganic (Se0, NaF) and less organic SEI components. The unique triple‐layer SEI with layer‐by‐layer dense structure alleviate the excessive electrolyte consumption with less gas evolution. As a result, the anode delivered long‐lifespan at 10 A g‐1 (383.7 mAh g‐1, 6000 cycles, 93.1%, 5 min/cycle). The Se‐induced triple‐layer SEI could be also be formed on high‐capacity SnS2 anode. This work provides a novel SEI model by anion‐tailored EDL towards stable sodium‐storage of high‐capacity anode for fast‐charging.

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Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Luo,

Yang,

Gai

et al. 2024

Angewandte Chemie

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Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Luo,

Yang,

Gai

et al. 2024

Angew Chem Int Ed

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Linking D‐Band Center Modulation with Rapid Reversible Sulfur Conversion Kinetics via Structural Engineering of VS₂

Xia,

Liu,

Chen

et al. 2024

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The rapid catalytic conversion toward polysulfides is considered to be an advantageous approach to boost the reaction kinetics and inhibit the shuttle effect in lithium‐sulfur (Li─S) batteries. However, the prediction of high catalytic activity Li─S catalysts has become challenging given the carelessness in the relationship between important electronic characteristics of catalysts and catalytic activity. Herein, the relationships between the D‐band regulation of catalysts with reaction kinetics toward polysulfides are described. Through the combination of experimental and theoretical analysis, the opportune upward shift of the D‐band center results in a favorable interaction with polysulfides, controlling the adsorption behavior of polysulfides. In addition, the electron regulation achieved by moderately moving up the D‐band center further reduces the reaction energy barrier through hybridization with polysulfides. Based on this, a composite catalyst Mo doped VS2/rGO as a host material is proposed, which provides impressive long‐term cycling stability and superior rate performance. This fundamental knowledge of the inherent connection between the D‐band center of the catalyst and the reaction Kinetics of polysulfides offers a rationale for the development of the Li─S catalyst and the modification of its activity.

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Biometabolically Derived Selenium Nanoparticles Armed with Protein Protective Suit toward High‐Performance Li‐Se Batteries

Cited by 3 publications

References 51 publications

Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Anion‐Tailored EDL Induced Triple‐Layer SEI on High‐Capacity Anodes Enabling Fast‐Charging and Durable Sodium‐Storage

Linking D‐Band Center Modulation with Rapid Reversible Sulfur Conversion Kinetics via Structural Engineering of VS₂

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