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Hauptverfasser: Zhiyin Yang, Cheng‐Wei Lin, Sophia Uemura, Mackenzie Anderson, Yuto Katsuyama, Maher F. El‐Kady, Yuzhang Li, Richard B. Kaner
Format: Artículo Open Access
Veröffentlicht: Wiley 2025
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Online-Zugang:https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.202500913
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author Zhiyin Yang
Cheng‐Wei Lin
Sophia Uemura
Mackenzie Anderson
Yuto Katsuyama
Maher F. El‐Kady
Yuzhang Li
Richard B. Kaner
author_facet Zhiyin Yang
Cheng‐Wei Lin
Sophia Uemura
Mackenzie Anderson
Yuto Katsuyama
Maher F. El‐Kady
Yuzhang Li
Richard B. Kaner
Zhiyin Yang
Cheng‐Wei Lin
Sophia Uemura
Mackenzie Anderson
Yuto Katsuyama
Maher F. El‐Kady
Yuzhang Li
Richard B. Kaner
collection Wiley Open Access
contents Vanadium Oxide with Molecular‐Level Conducting Pathways for High‐Rate Sodium‐Ion Batteries Zhiyin Yang Cheng‐Wei Lin Sophia Uemura Mackenzie Anderson Yuto Katsuyama Maher F. El‐Kady Yuzhang Li Richard B. Kaner ChemSusChem Vanadium oxides electrode materials for sodium‐ion batteries have gained considerable attention due to their outstanding electrochemical properties, yet they still suffer from slow ion transfer, poor conductivity, and fragile structures. These can be improved by molecule intercalation, where the intercalated molecules pillar the adjacent layers and enlarge the interlayer spacing. Conducting polyaniline (PANI) is a promising intercalation material for vanadium oxide, benefiting from its high electrical conductivity and good electrochemical activity. Intercalating PANI could tune the interlayer structure and improve electrochemical performance, but is limited by poor cycling and rate performance. In this report, an approach of intercalating a short‐chain aniline trimer (AT) into vanadium oxide (VO) is developed, enabled by a two‐step simple mixing process. The selective insertion mechanism of sodium ions into V 2 O 5 is systematically investigated. As a result, the ATVO electrode achieves an outstanding specific capacity of 408 mAh g at 0.1 A g −1 . A capacity retention of 78.7% after 800 cycles at a rate of 1 A g −1 is reached. This study provides a pathway to intercalate short‐chain conducting polymers into vanadium oxide to improve sodium‐ion battery electrode materials performance, which paves the way for synthesizing simple, safe, and low‐cost sodium‐ion storage materials with promising electrochemical performance. 10.1002/cssc.202500913 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/cssc.202500913
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id wiley_oa_10_1002_cssc_202500913
institution Wiley Open Access
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publishDate 2025
publisher Wiley
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spellingShingle Vanadium Oxide with Molecular‐Level Conducting Pathways for High‐Rate Sodium‐Ion Batteries
Zhiyin Yang
Cheng‐Wei Lin
Sophia Uemura
Mackenzie Anderson
Yuto Katsuyama
Maher F. El‐Kady
Yuzhang Li
Richard B. Kaner
ChemSusChem
Vanadium Oxide with Molecular‐Level Conducting Pathways for High‐Rate Sodium‐Ion Batteries Zhiyin Yang Cheng‐Wei Lin Sophia Uemura Mackenzie Anderson Yuto Katsuyama Maher F. El‐Kady Yuzhang Li Richard B. Kaner ChemSusChem Vanadium oxides electrode materials for sodium‐ion batteries have gained considerable attention due to their outstanding electrochemical properties, yet they still suffer from slow ion transfer, poor conductivity, and fragile structures. These can be improved by molecule intercalation, where the intercalated molecules pillar the adjacent layers and enlarge the interlayer spacing. Conducting polyaniline (PANI) is a promising intercalation material for vanadium oxide, benefiting from its high electrical conductivity and good electrochemical activity. Intercalating PANI could tune the interlayer structure and improve electrochemical performance, but is limited by poor cycling and rate performance. In this report, an approach of intercalating a short‐chain aniline trimer (AT) into vanadium oxide (VO) is developed, enabled by a two‐step simple mixing process. The selective insertion mechanism of sodium ions into V 2 O 5 is systematically investigated. As a result, the ATVO electrode achieves an outstanding specific capacity of 408 mAh g at 0.1 A g −1 . A capacity retention of 78.7% after 800 cycles at a rate of 1 A g −1 is reached. This study provides a pathway to intercalate short‐chain conducting polymers into vanadium oxide to improve sodium‐ion battery electrode materials performance, which paves the way for synthesizing simple, safe, and low‐cost sodium‐ion storage materials with promising electrochemical performance. 10.1002/cssc.202500913 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Vanadium Oxide with Molecular‐Level Conducting Pathways for High‐Rate Sodium‐Ion Batteries
topic ChemSusChem
url https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.202500913