Litcius/Paper detail

Ethanol as Solvent Additives with Competitive Effect for High-Stable Aqueous Zinc Batteries

Zhuocheng Tian, Hang Liu, Mengyuan Cheng, Lianmeng Cui, Rongyu Zhang, Xu Yang, Di Wu, Dongxue Wang, Jianlong Xia

2024ACS Applied Materials & Interfaces23 citationsDOI

Abstract

Aqueous zinc-ion batteries are emerging as promising sustainable energy-storage devices. However, their cyclic stability is still a great challenge due to the inevitable parasitic reaction and dendrite growth induced by water. Herein, a cosolvent strategy based on competitive effect is proposed to address the aforementioned challenges. Ethanol with a higher Gutmann donor number demonstrates lower polarity and better wettability on the Zn surface compared with water, which endows ethanol with the ability of minimizing water activity by weakening H bonds and preferentially adsorbing on the Zn electrode. The above competitive advantages synergistically contribute to inhibiting the decomposition of free water and dendrite growth. Besides, an organic–inorganic hybrid solid–electrolyte interphase layer is in situ built based on ethanol additives, where organic matrix suppresses water corrosion while inorganic fillers promote fast Zn 2+ diffusion. Consequently, the electrolyte with ethanol additives boosts a high reversibility of Zn deposition, long-term durability, as well as superior Zn 2+ diffusibility in both Zn half-cells (Zn||Cu and Zn||Zn batteries) and Zn full cells (Zn||PTCDA and Zn||VO 2 batteries). This work sheds light on a universal strategy to design a high-reversible and dendrite-free Zn anode for stable aqueous batteries.

Topics & Concepts

Materials scienceZincAqueous solutionSolventEthanolChemical engineeringInorganic chemistryOrganic chemistryMetallurgyChemistryEngineeringAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research
Ethanol as Solvent Additives with Competitive Effect for High-Stable Aqueous Zinc Batteries | Litcius