Topology‐Guided Design of 3D Zinc Anodes: From Electrochemical Modulation to Practical Prospects

材料科学 纳米技术 网络拓扑 阳极 可扩展性 储能 制作 计算机科学 纳米线 电化学 沉积(地质) 枝晶(数学) 软件部署 多孔性 电偶阳极 电化学储能 电场 纳米晶
作者
Funian Mo,Ziliang Li,Nana Li,Lichen Jin,Tao Yang,Haibo Hu
出处
期刊:Small methods [Wiley]
卷期号:9 (11): e01337-e01337 被引量:3
标识
DOI:10.1002/smtd.202501337
摘要

Zinc-based batteries have attracted considerable attention as promising candidates for next-generation energy storage, owing to their intrinsic safety, environmental sustainability, and cost-effectiveness. However, the practical deployment of these systems is hindered by significant challenges associated with zinc anodes, including dendrite formation, hydrogen evolution, "dead zinc" accumulation, and pronounced volume fluctuations during cycling. Recent advancements in 3D topological engineering have introduced transformative solutions by enabling precise control over local electric fields, ion transport pathways, and deposition behavior through innovative structural design. This review provides a comprehensive overview of current progress in the topology-guided design and fabrication of 3D zinc anodes, encompassing strategies such as nanowire arrays, porous metallic scaffolds, additive manufacturing, and laser processing. How these engineered topologies modulate key electrochemical characteristics is highlighted, such as zinc deposition kinetics, electric field uniformity, and ion concentration gradients, thereby effectively suppressing dendrite growth, mitigating parasitic side reactions, and accommodating volume fluctuations. Critical development bottlenecks, including limited long-term stability, integration complexity, and scalability, are thoroughly discussed. Finally, future research directions is proposed with a focus on intelligent material integration, precision manufacturing, and the structure-performance relationship, aiming to provide a foundational framework for advancing high-performance zinc anodes for safe, efficient, and scalable energy storage applications.
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