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Ultrathin Yet Effective: 90 nm ZnF <sub>2</sub> Layer for Stabilizing Zinc–Metal Anodes

Viet Phuong Nguyen, Minji Park, Young‐Woon Byeon, Suim Lim, Kanghoon Yim, Minsub Oh, Seungmin Hyun, Eun‐chae Jeon, Seung‐Mo Lee

2025ACS Energy Letters18 citationsDOI

Abstract

The practical use of aqueous zinc-ion batteries is limited by dendrite formation and interfacial degradation at the Zn-metal anode. Here, we demonstrate that an ultrathin ZnF 2 interfacial coating, merely 90 nm thick, significantly enhances anode stability by suppressing side reactions, promoting uniform Zn deposition, and providing moderate mechanical adhesion. Symmetric cells with ZnF 2 -coated Zn achieved lifespans of 1500 h at 0.5 mA cm –2 and 500 h at 3.0 mA cm –2 . Full cells with Mn x V 2 O 5 cathodes retained 82% capacity after 2000 cycles. Crucially, nanoscratch tests revealed that the optimum thickness of ZnF 2 films provided reasonable interfacial toughness, offering new insights into the mechanical–electrochemical codesign of artificial protective layers, factors that have often been overlooked or insufficiently investigated so far. This study advances surface engineering for Zn anodes and introduces interfacial mechanics as a design parameter for durable artificial protective layers in aqueous battery systems.

Topics & Concepts

AnodeCathodeMaterials scienceDendrite (mathematics)Aqueous solutionLayer (electronics)Battery (electricity)Chemical engineeringDegradation (telecommunications)NanotechnologyAqueous mediumSurface engineeringElectrochemistryScience, technology and societyAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesAdvancements in Battery Materials
Ultrathin Yet Effective: 90 nm ZnF <sub>2</sub> Layer for Stabilizing Zinc–Metal Anodes | Litcius