Litcius/Paper detail

Dissolution Inhibition via Intramolecular N···I Halogen Bond Enables High-Loading Zn-Organic Battery

Peng Yang, Jiahao Guo, Silong Lin, Yongzhu Fu, Wei Guo

2025Journal of the American Chemical Society16 citationsDOI

Abstract

The development of aqueous zinc-ion batteries faces persistent challenges in reconciling high mass-loading capabilities with extreme tolerance, particularly for organic cathodes prone to dissolution in aqueous electrolyte. Here, we present a halogen-bonded azo-based cathode material, 4,4′-azopyridine-iodide (AZPY-I), engineered through iodine-mediated molecular stabilization of pyridinic nitrogen sites. Analyses reveal that AZPY-I adopts a robust π–π conjugated framework stabilized by directional N···I halogen bonds, achieving ultralow solubility (<0.5 mg mL –1 in H 2 O) while introducing dual redox-active sites with six-electron transfer capability (N═N and I 2 moieties). The Zn||AZPY-I cell delivers a near-theoretical capacity of 202 mAh g –1 with a high mass loading of 22.8 mg cm –2 at 0.5 A g –1, sustaining a 92% capacity retention over 150 cycles. At an ultrahigh current density (8 A g –1, ∼34.5 C), the cell demonstrates exceptional cyclability for 150,000 cycles with 0.00032% capacity decay per cycle. This work establishes halogen-bonded molecular engineering as a universal paradigm for designing dissolution-resistant organic electrodes, bridging molecular crystallography with practical battery metrics.

Topics & Concepts

ChemistryIntramolecular forceDissolutionHalogenHalogen bondBattery (electricity)Inorganic chemistryZincOrganic chemistryPower (physics)AlkylPhysicsQuantum mechanicsAdvanced battery technologies researchOrganic and Molecular Conductors ResearchIonic liquids properties and applications