Abstract

Aqueous zinc-iodine (Zn-I₂) batteries are promising candidates for large-scale energy storage due to the merits of low cost and high safety. However, their commercial application is hindered by Zn corrosion and polyiodide shuttle at I₂ cathode. Herein, N,N-bis(2-hydroxyethyl)glycine (BHEG) based interfacial adsorption layers are constructed to stabilize Zn anodes and mitigate polyiodide shuttle according to ion-dipole interactions, by using a strategy of electrolyte additive. The tertiary amine (N(CH₂)₃) and carboxyl (─COO^-) groups in the deprotonated BHEG can reversibly capture H⁺ and dynamically neutralize OH^- ions, efficiently buffering the interfacial pH of Zn metal anodes and suppressing hydrogen evolution reactions. Additionally, the BHEG adsorption layers can repel 39.3% of H₂O molecules at the Zn interface, creating a "water-deficient" inner Helmholtz plane and preventing Zn corrosion. Significantly, the N(CH₂)₃ groups in BHEG also inhibit polyiodide shuttle at the I₂ cathode, which exhibits high adsorption energies of -0.88, -0.41, and -0.39 eV for I^-, I_2, and I₃ ^-, respectively. Attributing to these benefits, the Zn-I₂ battery can achieve a high areal capacity of 2.99 mAh cm^-2 and an extended cycling life of 2,000 cycles, even at a high mass loading of I₂ cathode (≈21.5 mg cm^-2).