Robust ring insoluble naphthoquinone derivative cathode with high loading and long cycle life for aqueous zinc organic batteries

Robust ring insoluble naphthoquinone derivative cathode with high loading and long cycle life for aqueous zinc organic batteries

Organic materials for aqueous zinc ion batteries have been attracted the attention of researchers because of their high safety, environmental friendliness, and structural designability. However, the limited specific capacity, unsatisfactory cycling durability, and unclear charge storage mechanism li...

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Bibliographic Details
Main Authors: Jiali Wang, Xinyu Gao, Yongwen Wang, Ruonan Pan, Zhen Liu, Xin Liu, Haijiao Xie, Feng Yu, Gang Wang, Tiantian Gu
Format: Article
Language:English
Published: Tsinghua University Press 2024-12-01
Series:Nano Research Energy
Subjects:
aqueous zinc ion batteries
organic molecules
high loading
electrochemical mechanism
synergistic effect
Online Access:https://www.sciopen.com/article/10.26599/NRE.2024.9120124
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Summary:Organic materials for aqueous zinc ion batteries have been attracted the attention of researchers because of their high safety, environmental friendliness, and structural designability. However, the limited specific capacity, unsatisfactory cycling durability, and unclear charge storage mechanism limit their development and applications. Herein, NTCDA-2,3-DNQ, an organic compound with a benzimidazole ring structure, was designed through the number and distribution of active sites as well as the adjustment of molecular weight, and applied as the cathode for aqueous zinc-ion batteries. NTNQ exhibits high specific capacity of 290.5 mAh·g–1 at 0.05 A·g–1, excellent rate performance of 133.3 mAh·g–1 at 15 A·g–1, and relatively stable cycle life with 81.7% capacity retention over 10,000 superlong cycles at 10 A·g–1. Furthermore, the synergistic effect of neighboring active sites and multi-electron Zn2+ storage reactions are further explored by density functional theory (DFT) calculations, and the results show that NTNQ could stores 4Zn2+ while transferring 8e– in the N-Zn-O pathway during the storage of Zn2+. Interestingly, NTNQ still exhibits high specific capacity and favorable cycling stability at multiple ultra-high loadings. This work provides important chances including the design concepts of the organic molecules and the investigation of the Zn2+ storage mechanism for high performance aqueous zinc ion batteries.
ISSN:2791-0091
2790-8119

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