Self‐Assembled Solid‐State Gel Catholyte Combating Iodide Diffusion and Self‐Discharge for a Stable Flexible Aqueous Zn–I2 Battery

Self‐Assembled Solid‐State Gel Catholyte Combating Iodide Diffusion and Self‐Discharge for a Stable Flexible Aqueous Zn–I2 Battery

Aqueous rechargeable zinc–iodine batteries (ARZIBs) represent a promising form of sustainable energy storage, having highly abundant and environmentally workable elements. The low utilization of solid iodine and self‐discharge due to the diffusive properties of the soluble polyiodides in aqueous med...

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Bibliographic Details
Published in:Advanced energy materials Vol. 10; no. 47
Main Authors: Sonigara, Keval K., Zhao, Jingwen, Machhi, Hiren K., Cui, Guanglei, Soni, Saurabh S.
Format: Journal Article
Language:English
Published: Weinheim Wiley Subscription Services, Inc 01-12-2020
Subjects:
Aqueous solutions
Block copolymers
Discharge
Energy storage
Ethylene oxide
iodide diffusion control
Iodine
Ion currents
Ion diffusion
Micelles
Multilayers
Polyethylene oxide
polymer gel self‐assembly
Rechargeable batteries
self‐discharge protection
solid–gel reaction
Stability
Storage batteries
Zinc
zinc–iodine batteries
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Summary:Aqueous rechargeable zinc–iodine batteries (ARZIBs) represent a promising form of sustainable energy storage, having highly abundant and environmentally workable elements. The low utilization of solid iodine and self‐discharge due to the diffusive properties of the soluble polyiodides in aqueous media hamper the stability and device design. The concept of building a solid‐state ARZIB with self‐discharge control by limiting iodide diffusion employing solid–gel reactions with water‐based gel‐embedded I3−/I− in block copolymer bearing highly active iodine components is demonstrated. The catholyte gel has an amphiphilic property that provides high solubility for iodine and better ionic conductivity from the cubic microcrystalline self‐assembled structures. This gel prevents long range iodide ion diffusion in multilayer self‐assemblies of the catholyte followed by the gel electrolyte layer due to self‐trapped polyiodides at the core–shell interface and inside the hydrophobic core of micelles. By contrast, positive zinc ions easily diffuse through the hydrophilic poly(ethylene oxide)‐water‐rich channels. This solid matrix results in a discharge capacity of 210 mAh g−1 (at 1 C rate) and stability with a retaining capacity of 94.3% after 500 cycles, including self‐discharge protection. The flexible module device shows excellent flexibility during deformations and the ability to power gadgets with stable performance. Solid–gel‐embedded iodine catholytes in amphiphilic‐block‐copolymer self‐assemblies selectively provide high redox species utilization and controlled iodide diffusion in the zinc–iodine battery. This unique design allows self‐discharge control with high capacity and easy fabrication of flexible solid‐state devices having robust operation.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.202001997