Rechargeable Iodine Batteries: Fundamentals, Advances, and Perspectives

Yang, Shuo; Guo, Xun; Lv, Haiming; Han, Cuiping; Chen, Ao; Tang, Zijie; Li, Xinliang; Chen, Zhi; Li, Hongfei

doi:10.1021/acsnano.2c06220

Cited by 57 publications

(21 citation statements)

References 123 publications

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“…[ 11,12 ] Nonetheless, ZIBs are encountering inadequate cycle life caused by the severe dissolution/diffusion of water‐soluble polyiodide intermediates in electrolytes as well as the poor stability of the Zn anode. [ 13–15 ]…”

Section: Introductionmentioning

confidence: 99%

Tuning Ion Transport at the Anode‐Electrolyte Interface via a Sulfonate‐Rich Ion‐Exchange Layer for Durable Zinc‐Iodine Batteries

Zhang

Huang

Guo

et al. 2023

Advanced Energy Materials

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Rechargeable aqueous zinc‐iodine batteries (ZIBs) are considered a promising newly‐developing energy‐storage system, but the corrosion and dendritic growth occurring on the anode seriously hinder their future application. Here, the corrosion mechanism of polyiodide is revealed in detail, showing that it can spontaneously react with zinc and cause rapid battery failure. To address this issue, a sulfonate‐rich ion‐exchange layer (SC‐PSS) is purposely constructed to modulate the transport and reaction chemistry of polyiodide and Zn2+ at the zinc/electrolyte interface. The resulting ZIBs can work properly over 6000 cycles with high‐capacity retention (90.2%) and reversibility (99.89%). Theoretical calculations and experimental characterization reveal that the SC‐PPS layer blocks polyiodide permeation through electrostatic repulsion, while facilitating desolvation of Zn(H2O)62+ and restricting undesirable 2D diffusion of Zn2+ by chemisorption.

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Section: Introductionmentioning

confidence: 99%

Tuning Ion Transport at the Anode‐Electrolyte Interface via a Sulfonate‐Rich Ion‐Exchange Layer for Durable Zinc‐Iodine Batteries

Zhang

Huang

Guo

et al. 2023

Advanced Energy Materials

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“…[ 1–3 ] Efficient and stable electrochemical activity of the zinc‐iodine system in aqueous electrolytes provides a desirable output voltage of around 1.29 eV [−0.76 V versus standard hydrogen electrode (SHE) for Zn/Zn 2+ and 0.53 V versus (SHE) for I 2 /I − redox couple] and a high theoretical capacity of 211 mAh g −1 with a flat discharge plateau. [ 4–6 ] Especially, the conversion reaction of iodine cathode helps to avert lattice distortion and structure collapse that degrade intercalation‐type electrodes, as well as the use of expensive ion‐selective membranes and electrocatalysts, thereby drawing wide attention among the community. [ 7–14 ] However, van der Waals forces linking iodine molecules within crystals are weak, which causes spontaneous sublimation and undesired thermal stability at ambient conditions and thus deteriorates the capacity and cyclic life of full batteries.…”

Section: Introductionmentioning

confidence: 99%

Conversion‐Type Organic‐Inorganic Tin‐Based Perovskite Cathodes for Durable Aqueous Zinc‐Iodine Batteries

Wang

Huang

Tang

et al. 2023

Advanced Energy Materials

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Aqueous metal-iodine batteries have recently attracted widespread attention, but their intrinsic issues such as the undesired shuttle effect and volatility of iodine hinder their reliable long-term performance. Herein, organic-inorganic MXDA 2 SnI 6 (MXDA 2+ denotes protonated m-xylylenediamine cation) perovskite microcrystals with a zero-dimensional arrangement of octahedral perovskite units offering high content of elemental iodine (46 wt% in the whole cathode) are proposed as conversion-type cathode materials for aqueous Zn-I 2 batteries. Iodide anions deliver reliable electrochemical activity and are effectively immobilized on the cathode to relieve the shuttle process by both physical steric hindrance and chemical adsorption offered by long-chain organic matrix and the presence of B-site Sn(II) cations in the MXDA 2 SnI 6 perovskite, respectively. Moreover, the formation of triiodide anions is alleviated in favor of a significant proportion of pentaiodide ions during the end of the charging process, enabled by increased formation energy of I 3 − and effective confinement via Sn-I…I halogen bonds and N-H…I hydrogen bonds, as revealed by density functional theory calculations.As a result, rechargeable aqueous Zn-I 2 batteries are realized that achieve a champion capacity of over 206 mAh g −1 I at 0.5 A g −1 (close to the theoretical limit), and outstanding rate capability with a capacity retention of 87% at 3 A g −1 . Suppressed shuttle of polyiodide anions endows aqueous Zn-I 2 batteries with prolonged cyclic stability, namely high capacity retention of 95% after 5700 cycles at 1 A g −1 . This study promotes the development of high-performance cathode materials for metal-I 2 batteries by revealing the feasibility of using ionic perovskites as conversion-type cathodes.

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“…Promoting renewable, safe, highly cost‐effective, and environmentally‐friendly energy technologies is an essential scientific responsibility [3–5] . The rechargeable Li/Na‐I 2 batteries possess a high average operating voltage (≈2.9 V), high theoretical capacity (211 mAh g −1 ), and low cost of iodine, making them more economical than their counterparts [6–9] . However, the development of rechargeable Li/Na‐I 2 batteries has been severely limited in the past few decades by their low thermal stability and poor dynamics [10–12] .…”

Section: Introductionmentioning

confidence: 99%

“…[3][4][5] The rechargeable Li/Na-I 2 batteries possess a high average operating voltage ( � 2.9 V), high theoretical capacity (211 mAh g À 1 ), and low cost of iodine, making them more economical than their counterparts. [6][7][8][9] However, the development of rechargeable Li/Na-I 2 batteries has been severely limited in the past few decades by their low thermal stability and poor dynamics. [10][11][12] In addition, the high solubility of iodine and the intermediate product iodide in the electrolyte produced during the cell cycle can lead to a shuttle effect, resulting in self-discharge and low Coulombic efficiency.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen‐Bonded Organic Framework for High‐Performance Lithium/Sodium‐Iodine Organic Batteries

et al. 2022

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The rechargeable lithium/sodium-iodine battery (Li/Na-I 2 ) is a promising candidate for meeting the growing energy demand. Herein, a flexible hydrogenbonded organic framework (HOF) linked to the Ti 3 C 2 T x MXene complex (HOF@Ti 3 C 2 T x ) has been presented for iodine loading. HOF is self-assembled by organic monomers through hydrogen bonding interactions between each monomer. It leads to numerous cavities in HOF structure, which can encapsulate iodine through various adsorptive sites and intermolecular interactions. The unique structure of complex can accelerate the nucleation of iodine, achieve fast reaction kinetics, stabilize iodide and retard the shuttle effect, thus improving the cycling stability of I 2 -based batteries. The I 2 /HOF@Ti 3 C 2 T x exhibits large reversible capacities of 260.2 and 207.6 mAh g À 1 at 0.2 C after repeated cycling for Li-I 2 and Na-I 2 batteries, respectively. This work can gain insights into the HOF-related energy storage application with reversible iodine encapsulation and its related redox reaction mechanisms with Li and Na metal ions.

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Rechargeable Iodine Batteries: Fundamentals, Advances, and Perspectives

Cited by 57 publications

References 123 publications

Tuning Ion Transport at the Anode‐Electrolyte Interface via a Sulfonate‐Rich Ion‐Exchange Layer for Durable Zinc‐Iodine Batteries

Tuning Ion Transport at the Anode‐Electrolyte Interface via a Sulfonate‐Rich Ion‐Exchange Layer for Durable Zinc‐Iodine Batteries

Conversion‐Type Organic‐Inorganic Tin‐Based Perovskite Cathodes for Durable Aqueous Zinc‐Iodine Batteries

Hydrogen‐Bonded Organic Framework for High‐Performance Lithium/Sodium‐Iodine Organic Batteries

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