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Autores principales: Ruilin Zhu, Xin Tao, Zemin He, Lianghao Yu, Tiantian Wei, Haoliang Xie, Jingjing Xie, Pan Li, Kongqing Yu, Jun Li, Huile Jin, Shun Wang, Jichang Wang
Formato: Artículo Open Access
Publicado: Wiley 2025
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Acceso en línea:https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.202501774
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author Ruilin Zhu
Xin Tao
Zemin He
Lianghao Yu
Tiantian Wei
Haoliang Xie
Jingjing Xie
Pan Li
Kongqing Yu
Jun Li
Huile Jin
Shun Wang
Jichang Wang
author_facet Ruilin Zhu
Xin Tao
Zemin He
Lianghao Yu
Tiantian Wei
Haoliang Xie
Jingjing Xie
Pan Li
Kongqing Yu
Jun Li
Huile Jin
Shun Wang
Jichang Wang
Ruilin Zhu
Xin Tao
Zemin He
Lianghao Yu
Tiantian Wei
Haoliang Xie
Jingjing Xie
Pan Li
Kongqing Yu
Jun Li
Huile Jin
Shun Wang
Jichang Wang
collection Wiley Open Access
contents Optimizing the Performance of Sodium‐Ion Battery through Suppressing ZnS Anode Alloy Reaction Ruilin Zhu Xin Tao Zemin He Lianghao Yu Tiantian Wei Haoliang Xie Jingjing Xie Pan Li Kongqing Yu Jun Li Huile Jin Shun Wang Jichang Wang ChemSusChem Zinc sulfide (ZnS) is a promising anode material for sodium‐ion batteries (SIBs) due to its high theoretical capacity and cost‐effectiveness. However, the alloying reaction of ZnS causes severe volume expansion, leading to material pulverization and capacity decay. To address this, a sandwich‐structured ZnS/porous MXene (ZnS/PMX) composite is designed, where ZnS nanoparticles are anchored on PMX porous layers via ZnOTi interfacial bonding. The nanoporous structure of PMX creates vertical ion transport pathways, enabling faster sodium‐ion diffusion and overcoming the limitations of conventional 2D MXene. Additionally, the confinement effect of PMX suppresses the alloying reaction of ZnS, enhancing its structural stability. As an SIB anode, ZnS/PMX maintains capacities of 414.8 mA h g − 1 after 2100 cycles at 5.0 A g − 1 , 322.9 mA h g − 1 after 3300 cycles at 10.0 A g − 1 , and 276.9 mA h g − 1 after 4100 cycles at 20.0 A g − 1 . This performance benefits from the confinement effects of PMX, which effectively suppresses the alloying reaction and enhances ZnS stability. The results shed new light on the design of metal sulfide/MXene hybrid materials for alkali metal batteries. 10.1002/cssc.202501774 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/cssc.202501774
format Artículo Open Access
id wiley_oa_10_1002_cssc_202501774
institution Wiley Open Access
license_str_mv http://onlinelibrary.wiley.com/termsAndConditions#vor
publishDate 2025
publisher Wiley
record_format wiley_oa
spellingShingle Optimizing the Performance of Sodium‐Ion Battery through Suppressing ZnS Anode Alloy Reaction
Ruilin Zhu
Xin Tao
Zemin He
Lianghao Yu
Tiantian Wei
Haoliang Xie
Jingjing Xie
Pan Li
Kongqing Yu
Jun Li
Huile Jin
Shun Wang
Jichang Wang
ChemSusChem
Optimizing the Performance of Sodium‐Ion Battery through Suppressing ZnS Anode Alloy Reaction Ruilin Zhu Xin Tao Zemin He Lianghao Yu Tiantian Wei Haoliang Xie Jingjing Xie Pan Li Kongqing Yu Jun Li Huile Jin Shun Wang Jichang Wang ChemSusChem Zinc sulfide (ZnS) is a promising anode material for sodium‐ion batteries (SIBs) due to its high theoretical capacity and cost‐effectiveness. However, the alloying reaction of ZnS causes severe volume expansion, leading to material pulverization and capacity decay. To address this, a sandwich‐structured ZnS/porous MXene (ZnS/PMX) composite is designed, where ZnS nanoparticles are anchored on PMX porous layers via ZnOTi interfacial bonding. The nanoporous structure of PMX creates vertical ion transport pathways, enabling faster sodium‐ion diffusion and overcoming the limitations of conventional 2D MXene. Additionally, the confinement effect of PMX suppresses the alloying reaction of ZnS, enhancing its structural stability. As an SIB anode, ZnS/PMX maintains capacities of 414.8 mA h g − 1 after 2100 cycles at 5.0 A g − 1 , 322.9 mA h g − 1 after 3300 cycles at 10.0 A g − 1 , and 276.9 mA h g − 1 after 4100 cycles at 20.0 A g − 1 . This performance benefits from the confinement effects of PMX, which effectively suppresses the alloying reaction and enhances ZnS stability. The results shed new light on the design of metal sulfide/MXene hybrid materials for alkali metal batteries. 10.1002/cssc.202501774 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Optimizing the Performance of Sodium‐Ion Battery through Suppressing ZnS Anode Alloy Reaction
topic ChemSusChem
url https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.202501774