A rechargeable iodine-carbon battery that exploits ion intercalation and iodine redox chemistry

Lu, Ke; Hu, Ziyu; Ma, Jizhen; Ma, Houyi; Dai, Liming; Zhang, Jintao

doi:10.1038/s41467-017-00649-7

Cited by 189 publications

(166 citation statements)

References 54 publications

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“…As prospective alternatives for Li‐ion batteries, rechargeable zinc‐iodine aqueous batteries (ZIABs) are emerging for large‐scale energy storage systems because of high theoretical capacities and energy densities (around 169 mAh g −1 and 220 Wh kg −1 based on the total mass of active cathode and anode materials), abundant raw materials, environmental friendliness, non‐flammable aqueous electrolytes, and simplified battery packaging technology in air. [ 25–34 ] However, ZIABs suffer from the serious overcharge problem due to the close redox potentials of Zn stripping/platting and hydrogen (H 2 ) evolution. [ 35–38 ] For example, a recent pressure sensor analysis of Zn anode in a slightly acidic electrolyte (pH = 4.57) manifested the side reaction rate of H 2 evolution up to 3 × 10 −7 moles per cycle.…”

Section: Figurementioning

confidence: 99%

A Stimulus‐Responsive Zinc–Iodine Battery with Smart Overcharge Self‐Protection Function

et al. 2020

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Zinc-iodine aqueous batteries (ZIABs) are highly attractive for grid-scale energy storage due to their high theoretical capacities, environmental friendliness, and intrinsic non-flammability. However, because of the close redox potential of Zn stripping/platting and hydrogen evolution, slight overcharge of ZIABs would induce drastic side reactions, serious safety concerns, and battery failure. A novel type of stimulus-responsive zinc-iodine aqueous battery (SR-ZIAB) with fast overcharge self-protection ability is demonstrated by employing a smart pH-responsive electrolyte. Operando spectroelectrochemical characterizations reveal that the battery failure mechanism of ZIABs during overcharge arises from the increase of electrolyte pH induced by hydrogen evolution as well as the consequent irreversible formation of insulating ZnO at anode and soluble Zn(IO 3 ) 2 at cathode. Under overcharge conditions, the designed SR-ZIABs can be rapidly switched off with capacity degrading to 6% of the initial capacity, thereby avoiding continuous battery damage. Importantly, SR-ZIABs can be switched on with nearly 100% of capacity recovery by re-adjusting the electrolyte pH. This work will inspire the development of aqueous Zn batteries with smart self-protection ability in the overcharge state.Stimulus-responsive materials and devices are attracting intensive attention because of the ever-increasing demand for intelligent devices. [1][2][3][4][5][6] In particular, integrating stimulus-responsive functions into rechargeable batteries shows great potential to revolutionize electrochemical energy storage systems for future smart devices. [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] Currently, the three most eye-catching stimulus-responsive batteries are temperature-responsive Li-ion batteries, [11,14,16,20] photo-responsive Li-ion batteries, [7,17,18] and self-healing Li-ion batteries. [8,13,15,19] Despite the availability of aforementioned stimulus-responsive batteries, the developed stimulus responses for rechargeable batteries are still sparse owing to the complexity and compatibility of battery architectures. [24] Moreover, the reported stimulus-responsive functions are mainly integrated into Li-ion batteries. [8,[13][14][15][16][17][18][19][20] However, the limited Li resources and high flammability of Li-ion batteries severely impede their commercial applications for stationary energy storage systems. Therefore, it is highly desired to explore new stimulus-responsive systems beyond Li-ion batteries.As prospective alternatives for Li-ion batteries, rechargeable zinc-iodine aqueous batteries (ZIABs) are emerging for largescale energy storage systems because of high theoretical capacities and energy densities (around 169 mAh g −1 and 220 Wh kg −1 based on the total mass of active cathode and anode materials), abundant raw materials, environmental friendliness, non-flammable aqueous electrolytes, and simplified battery packaging technology in air. [25][26][27][28][29][30][31][32][33][34] However, ZIABs su...

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Section: Figurementioning

confidence: 99%

A Stimulus‐Responsive Zinc–Iodine Battery with Smart Overcharge Self‐Protection Function

et al. 2020

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“…Compared to sulfur and oxygen, halogens (Br 2 and I 2 ) have reversible electrochromic window and excellent reversible redox reactions at high potentials . Thus, halogens have been demonstrated in various rechargeable batteries, e.g., Li//I 2 battery, Zn//I 2 battery, Al//I 2 battery, Na//I 2 battery, Zn//Br 2 battery, and Mg//Br 2 . However, these state‐of‐the‐art rechargeable batteries fail to be simultaneously endowed with both multi‐stimuli‐responsive properties and high energy densities owing to the complexity and compatibility of battery architectures .…”

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confidence: 99%

A Dual‐Stimuli‐Responsive Sodium‐Bromine Battery with Ultrahigh Energy Density

et al. 2018

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Stimuli-responsive energy storage devices have emerged for the fast-growing popularity of intelligent electronics. However, all previously reported stimuli-responsive energy storage devices have rather low energy densities (<250 Wh kg ) and single stimuli-response, which seriously limit their application scopes in intelligent electronics. Herein, a dual-stimuli-responsive sodium-bromine (Na//Br ) battery featuring ultrahigh energy density, electrochromic effect, and fast thermal response is demonstrated. Remarkably, the fabricated Na//Br battery exhibits a large operating voltage of 3.3 V and an energy density up to 760 Wh kg , which outperforms those for the state-of-the-art stimuli-responsive electrochemical energy storage devices. This work offers a promising approach for designing multi-stimuli-responsive and high-energy rechargeable batteries without sacrificing the electrochemical performance.

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“…Reprinted with permission from Ref. [197], Copyright 2017, Nature Group aligned SWCNT array also displayed a high conversion efficiency of 5.5%, comparable to 5.6% obtained with a Pt-based DSSC tested under the same conditions [195]. In addition, carbon catalysts comprised of CNTs coated onto a flexible graphene paper achieved 83% conversion efficiency of that of a Pt electrode [196].…”

Section: Carbon-based Metal-free Catalysts For Solar Cells and Metal-mentioning

confidence: 70%

“…Inspired by the excellent electrocatalytic activities induced by heteroatom-doping for metal-air batteries [25,202] and its significant effects on enhancing capacity and cycling stability of Na/Li-ion batteries [203], Lu et al [197] used hierarchical porous N,P-co-doped carbon matrixes as hosts for I 2 loading in I 2 -based batteries (Fig. 10e).…”

Section: Carbon-based Metal-free Catalysts For Solar Cells and Metal-mentioning

confidence: 99%

“…However, the development of economically efficient and highly conducting iodine-based cathodes with stable and high iodine loading is challenging [197]. Several carbon hosts, including carbon black [198], nanoporous carbon [199], vertically aligned carbon nanotubes [200], and porous carbon microtubes [201], have been employed to load I 2 for Li-I 2 batteries.…”

Section: Carbon-based Metal-free Catalysts For Solar Cells and Metal-mentioning

confidence: 99%

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Carbon-Based Metal-Free Electrocatalysis for Energy Conversion, Energy Storage, and Environmental Protection

Xiao

Zou

et al. 2018

Electrochem. Energ. Rev.

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157

103

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Carbon-based metal-free catalysts possess desirable properties such as high earth abundance, low cost, high electrical conductivity, structural tunability, good selectivity, strong stability in acidic/alkaline conditions, and environmental friendliness. Because of these properties, these catalysts have recently received increasing attention in energy and environmental applications. Subsequently, various carbon-based electrocatalysts have been developed to replace noble metal catalysts for low-cost renewable generation and storage of clean energy and environmental protection through metal-free electrocatalysis. This article provides an up-to-date review of this rapidly developing field by critically assessing recent advances in the mechanistic understanding, structure design, and material/device fabrication of metal-free carbon-based electrocatalysts for clean energy conversion/storage and environmental protection, along with discussions on current challenges and perspectives. Graphical AbstractKeywords Metal-free electrocatalysis · Carbon-based catalysts · Energy conversion and storage · Environmental protection

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A rechargeable iodine-carbon battery that exploits ion intercalation and iodine redox chemistry

Cited by 189 publications

References 54 publications

A Stimulus‐Responsive Zinc–Iodine Battery with Smart Overcharge Self‐Protection Function

A Stimulus‐Responsive Zinc–Iodine Battery with Smart Overcharge Self‐Protection Function

A Dual‐Stimuli‐Responsive Sodium‐Bromine Battery with Ultrahigh Energy Density

Carbon-Based Metal-Free Electrocatalysis for Energy Conversion, Energy Storage, and Environmental Protection

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