<p>The formation of zinc dendrites is a significant obstacle to commercializing zinc-ion batteries. Although the discrepancy between the fast electrochemical reaction kinetics and the comparatively sluggish mass transfer leads to the formation and growth of dendrites, a profound understanding of how the relationship between the two factors influences dendrite formation is essential. Here, through investigating a series of urea derivatives for regulating Zn<sup>2+</sup> plating, we find that achieving a better balance between electrochemical reaction kinetics and the mass transfer rate is crucial for effectively suppressing dendrite formation. A dimensionless constant, K, is proposed to quantify the balance between these two factors. As a result, the electrolyte with N, N-dimethylurea has the highest K value, enabling cumulative capacities of 11,000 mAh cm<sup>−2</sup> for Zn | |Zn cells and 7,500 mAh cm<sup>−2</sup> for Zn | |Cu cells achieved at a current density of 10 mA cm<sup>−2</sup>. Furthermore, the Zn | |Zn<sub>0.25</sub>V<sub>2</sub>O<sub>5</sub>·nH<sub>2</sub>O pouch cell with a mass loading of 60 mg cm<sup>−2</sup> delivers a capacity of 6.95 Ah and demonstrates stable cycling performance using the modified electrolyte. This work provides theoretical insights into governing the formation and growth of zinc dendrites.</p>

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Balanced electrochemical reaction kinetics and mass transfer for stable zinc negative electrode

  • Ao Chen,
  • Shuo Yang,
  • Funian Mo,
  • Qing Li,
  • Zhuoxi Wu,
  • Zhaodong Huang,
  • Ze Chen,
  • Yiqiao Wang,
  • Hu Hong,
  • Zhiquan Wei,
  • Hui Yang,
  • Chunyi Zhi

摘要

The formation of zinc dendrites is a significant obstacle to commercializing zinc-ion batteries. Although the discrepancy between the fast electrochemical reaction kinetics and the comparatively sluggish mass transfer leads to the formation and growth of dendrites, a profound understanding of how the relationship between the two factors influences dendrite formation is essential. Here, through investigating a series of urea derivatives for regulating Zn2+ plating, we find that achieving a better balance between electrochemical reaction kinetics and the mass transfer rate is crucial for effectively suppressing dendrite formation. A dimensionless constant, K, is proposed to quantify the balance between these two factors. As a result, the electrolyte with N, N-dimethylurea has the highest K value, enabling cumulative capacities of 11,000 mAh cm−2 for Zn | |Zn cells and 7,500 mAh cm−2 for Zn | |Cu cells achieved at a current density of 10 mA cm−2. Furthermore, the Zn | |Zn0.25V2O5·nH2O pouch cell with a mass loading of 60 mg cm−2 delivers a capacity of 6.95 Ah and demonstrates stable cycling performance using the modified electrolyte. This work provides theoretical insights into governing the formation and growth of zinc dendrites.