<p>Aqueous Zn–I<sub>2</sub> batteries hold significant promise for large-scale energy storage applications; however, their practical implementation is constrained by coupled interfacial instabilities, including Zn dendrite growth, parasitic hydrogen evolution and polyiodide shuttling. Here we report a dual-network hydrogel electrolyte that stabilizes Zn and iodine chemistries through a synergistic, cross-scale design spanning molecular conformation regulation, charge microenvironment engineering and network topology control. By precisely tailoring the local charge microenvironment, the hydrogel electrostatically excludes polyiodide species to mitigate the shuttle effect, while simultaneously constructing low-energy pathways for Zn<sup>2+</sup> migration, enabling differentiated ion regulation. The interconnected porous architecture further homogenizes ionic conduction and modulates three-dimensional Zn<sup>2+</sup> flux at the Zn interface, delivering dendrite-free Zn plating/stripping for over 3500 and 800&#xa0;h at areal capacities of 1 and 10&#xa0;mAh&#xa0;cm<sup>−2</sup>, respectively. In Zn–I<sub>2</sub> full cells, stable cycling is maintained for 20,000 cycles at a high rate of 10&#xa0;C. This work establishes an integrated molecular-to-mesoscale electrolyte design strategy for advancing highly stable aqueous Zn–I<sub>2</sub> batteries. </p>

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Ion-Sieving Dual-Network Hydrogel Electrolytes Couple Accelerated Ion Transport with Iodide Shuttle Suppression in Aqueous Zn–I2 Batteries

  • Ming Chen,
  • Jia Cheng,
  • Yixin Zhao,
  • Wei Fu,
  • Wen Li,
  • Yunhai Zhu,
  • Fanlu Meng

摘要

Aqueous Zn–I2 batteries hold significant promise for large-scale energy storage applications; however, their practical implementation is constrained by coupled interfacial instabilities, including Zn dendrite growth, parasitic hydrogen evolution and polyiodide shuttling. Here we report a dual-network hydrogel electrolyte that stabilizes Zn and iodine chemistries through a synergistic, cross-scale design spanning molecular conformation regulation, charge microenvironment engineering and network topology control. By precisely tailoring the local charge microenvironment, the hydrogel electrostatically excludes polyiodide species to mitigate the shuttle effect, while simultaneously constructing low-energy pathways for Zn2+ migration, enabling differentiated ion regulation. The interconnected porous architecture further homogenizes ionic conduction and modulates three-dimensional Zn2+ flux at the Zn interface, delivering dendrite-free Zn plating/stripping for over 3500 and 800 h at areal capacities of 1 and 10 mAh cm−2, respectively. In Zn–I2 full cells, stable cycling is maintained for 20,000 cycles at a high rate of 10 C. This work establishes an integrated molecular-to-mesoscale electrolyte design strategy for advancing highly stable aqueous Zn–I2 batteries.