Ultrastable Electrolytic Zn–I<sub>2</sub> Batteries Based on Nanocarbon Wrapped by Highly Efficient Single‐Atom Fe‐NC Iodine Catalysts

Wang, Yueyang; Jin, Xiangrong; Xiong, Jiawei; Zhu, Qingyi; Li, Qi; Wang, Runze; Li, Jiazhan; Fan, Yanchen; Zhao, Yi; Sun, Xiaoming

doi:10.1002/adma.202404093

Advanced Materials

2024

DOI: 10.1002/adma.202404093

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Ultrastable Electrolytic Zn–I₂ Batteries Based on Nanocarbon Wrapped by Highly Efficient Single‐Atom Fe‐NC Iodine Catalysts

Yueyang Wang,

Xiangrong Jin,

Jiawei Xiong

et al.

Abstract: Aqueous Zn‐iodine (Zn‐I2) conversion batteries with iodine redox chemistry suffers the severe polyiodide shuttling and sluggish redox kinetics, which impede the battery lifespan and rate capability. Herein, we introduce an ultrastable Zn‐I2 battery based on single‐atom Fe‐N‐C encapsulated high‐surface‐area carbon (HC@FeNC) as the core‐shell cathode materials, which accelerate the I−/I3−/I° conversion significantly. The robust chemical‐physical interaction between polyiodides and Fe‐N4 sites tightly binds the p… Show more

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Cited by 10 publications

References 61 publications

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Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Gao,

Liu,

Guo

et al. 2024

Adv Funct Materials

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Active iodine dissolution and polyiodide shuttle are two major obstacles hindering the application of zinc‐iodine batteries (ZIBs). Designing functional carriers with strong physisorption/chemisorption capability, abundant active sites, and high catalytic activity for iodine redox reaction kinetics, is considered an effective strategy to solve the current problems of ZIBs. In this work, Fe, Co, Ni‐doping porous carbon (FeCoNi) is comprehensively investigated as carrier material to prepare the iodine‐loading cathode of FeCoNi@I2. On the basis of experimental tests and theoretical calculations, the introduction of FeCoNi trimetallic atoms effectively regulates the electronic structure, charge distribution, active sites, and electronic conductivity of porous carbon substrate, promoting the iodine conversion reaction kinetics as well as chemisorption capability for iodine species, which is conducive to inhibit the polyiodide shuttle and active iodine dissolution. As expected, Zn//FeCoNi@I2 batteries exhibit high specific capacity and strong self‐discharge resistance capability, and the reversible capacity of FeCoNi@I2 cathode stabilizes at 108.8 mAh g−1 after 13000 cycles at 1 A g−1, and 94.7 mAh g−1 after 14000 cycles at 3 A g−1. This work will open new horizons for the structural design of catalyst‐type carrier materials for durable ZIBs, and facilitate the application of trimetallic atom‐doped porous carbon in high‐performance secondary batteries.

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Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Gao,

Liu,

Guo

et al. 2024

Adv Funct Materials

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Confining Iodine into Metal‐Organic Framework Derived Metal‐Nitrogen‐Carbon for Long‐Life Aqueous Zinc‐Iodine Batteries

Guo,

Xu,

Tang

et al. 2024

Advanced Materials

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Aqueous zinc–iodine batteries (AZIBs) are highly appealing for energy requirements owing to their safety, cost‐effectiveness, and scalability. However, the inadequate redox kinetics and severe shuttling effect of polyiodide ions impede their commercial viability. Herein, several Zn‐MOF‐derived porous carbon materials are designed, and the further preparation of iron–doped porous carbon (Fe–N–C, M9) with varied Fe doping contents is optimized based on a facile self‐assembly/carbonization approach. M9, with atomic Fe coordinated to nitrogen atoms, is employed as an efficient cathode host for AZIBs. Functional modifications of porous carbon hosts involving the doping species and levels are investigated. The adsorption tests, in situ Raman spectroscopy, and in situ UV–vis results demonstrate the adsorption capability and charge‐discharge mechanism for the iodine species. Furthermore, experimental findings and theoretical analyses have proven that the redox conversion of iodine is enhanced through a physicochemical confinement effect. This study offers basic principles for the strategic design of single‐atom dispersed carbon as an iodine host for high‐performance AZIBs. Flexible soft–pack battery and wearable microbattery applications also have implications for future long‐life aqueous battery designs.

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Size Confinement Strategy Effect Enables Advanced Aqueous Zinc–Iodine Batteries

Li,

Yang,

et al. 2024

Advanced Energy Materials

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Aqueous Zn–I2 batteries have considerable potential owing to their environmental friendliness and high safety. However, the slow iodine conversion kinetics and shuttle effect prevent their practical applicability. In this study, a series of Zn‐MOF‐74 rods with controllable diameters of 40–500 nm are facilely prepared, denoted as P1–P5. A size confinement strategy effect of Zn‐MOF‐74 derived porous carbon as iodine hosts is proposed to suppress the formation of undesirable iodine species, such as I3− and I5−. Moreover, the graphitization degree of porous carbon samples, including P2‐900, P2‐1000, and P2‐1100, play a critical effect on the iodine conversion kinetics. The P2‐1000 sample possesses a high conductive skeleton and abundant mesopores, which improve the adsorption ability toward iodine species. The electrochemical tests and the in situ technology reveal the size confinement strategy effect and the conversion mechanism of iodine. As a result, the I2@P2‐1000 cathode exhibits a superior discharge capacity of 179.9 mA h g−1 at 100 mA g−1 and exceptional long‐term cycle ability after 5000 cycles. Furthermore, the soft batteries and the flexible quasi‐solid‐state batteries are capable of powering devices, promising to exhibit tremendous adaptability and realize flexible electronic devices in various scenarios.

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Ultrastable Electrolytic Zn–I₂ Batteries Based on Nanocarbon Wrapped by Highly Efficient Single‐Atom Fe‐NC Iodine Catalysts

Cited by 10 publications

References 61 publications

Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Confining Iodine into Metal‐Organic Framework Derived Metal‐Nitrogen‐Carbon for Long‐Life Aqueous Zinc‐Iodine Batteries

Size Confinement Strategy Effect Enables Advanced Aqueous Zinc–Iodine Batteries

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Ultrastable Electrolytic Zn–I2 Batteries Based on Nanocarbon Wrapped by Highly Efficient Single‐Atom Fe‐NC Iodine Catalysts

Cited by 10 publications

References 61 publications

Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Trimetallic Atom‐Doped Functional Carbon Catalyst Enables Fast Redox Kinetics and Durable Cyclic Stability of Zinc‐Iodine Batteries

Confining Iodine into Metal‐Organic Framework Derived Metal‐Nitrogen‐Carbon for Long‐Life Aqueous Zinc‐Iodine Batteries

Size Confinement Strategy Effect Enables Advanced Aqueous Zinc–Iodine Batteries

Contact Info

Product

Resources

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Ultrastable Electrolytic Zn–I₂ Batteries Based on Nanocarbon Wrapped by Highly Efficient Single‐Atom Fe‐NC Iodine Catalysts