What question did this study set out to answer?

To develop a wood-based electrolyte that addresses stability issues in zinc-ion batteries under high discharge conditions.

March 7, 2026

Wood-Structured Electrolyte for Ultra-Stable Zinc-Ion Batteries Under High Discharge Conditions.

Key Points

To develop a wood-based electrolyte that addresses stability issues in zinc-ion batteries under high discharge conditions.
Developed a hierarchical heterogeneous interconnected structure (HHIS) electrolyte using wood.
Investigated Zn<sup>2+</sup> transport mechanisms in the HHIS during battery cycling.
Conducted cycling tests to assess performance at varying depths of discharge.
Achieved over 9000 hours of cycling stability with the new electrolyte.
Maintained over 3300 hours of operation at 83.1% depth of discharge.
Outperformed previous studies in terms of longevity and stability under high current conditions.

Abstract

Aqueous zinc-ion batteries (AZIBs) operate stably at low depth of discharge (DOD) but suffer severe Zn2+ transport imbalance, hydrogen evolution, and plating/stripping at high DOD (> 70%). Here, we present a radial wood-based hierarchical heterogeneous interconnected structure (HHIS) electrolyte. HHIS is without low-tortuosity channels, but during cycling, Zn2+ predominantly migrates along laterally oriented vessels, fibers, and rays via pit coordination, ensuring uniform deposition. Leveraging these synergistic effects, HHIS stabilizes the Zn anode under high current, enabling > 9000 h of cycling and > 3300 h at 83.1% DOD, surpassing previous reports. This work directly converts wood into a high-performance electrolyte and establishes a HHIS design strategy for addressing high-DOD instability in AZIBs and advancing electrolyte commercialization.

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Cite This Study

Wei et al. (Wed,) studied this question.

synapsesocial.com/papers/69abc1b45af8044f7a4ea973 https://doi.org/https://doi.org/10.1002/adma.202522128

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