Litcius/Paper detail

Boosting iodine redox kinetics through the inherent electrostatic interaction and electron donor capability of gelatin binder

Min Chen, Xinxin Han, Yicai Pan, Hao-Ran Tu, Jiahao Zhu, Mengmeng Shao, Keren Zheng, Wenlong Wang, Kunquan Li, Xiaochang Qiao, Lutong Shan, Xiaodong Shi

2025Nano Materials Science6 citationsDOIOpen Access PDF

Abstract

The notorious shuttle effect of polyiodides in aqueous Zinc-iodine (Zn-I<sub>2</sub>) batteries impedes their practical application, which renders it imperative to address this issue. Here, we report natural gelatin as an advanced aqueous binder for iodine-loading cathode to enable stable and efficient Zn-I<sub>2</sub> batteries. The positively charged region in gelatin presents electrostatic attraction to the iodine species, while the electron-rich regions could donate electrons to form physical or even covalent bonds with iodine species, thus inhibiting polyiodides shuttle effect and boosting redox reaction. A high reversible capacity of 138 mAh g<sup>−1</sup> after 3 000 cycles at 2C and an ultra-long cycling stability of 30 000 cycles at 25C with 107 mAh g<sup>−1</sup> capacity was achieved. Gelatin binder also can accommodate high iodine-loading (∼10 ​mg) cathode, punch cells, and severe temperature conditions (−10 °C and 60 ​°C). In-situ UV–vis absorption spectroscopy, in-situ Raman spectra and theoretical calculation revealed the critical role of gelatin binder in suppressing polyiodide shuttling and accelerating reaction kinetics. This work uncovers the potential of natural low-cost binder material in advanced Zn-I<sub>2</sub> batteries and drives future study of designing functional binders. © 2025 The Authors.

Topics & Concepts

GelatinRedoxKineticsIodineBoosting (machine learning)ElectronMaterials scienceChemistryChemical engineeringPhotochemistryInorganic chemistryComputer scienceOrganic chemistryEngineeringPhysicsQuantum mechanicsMachine learningCrystallography and molecular interactionsAnesthesia and Sedative AgentsAnesthesia and Neurotoxicity Research