<p>Carbonaceous zinc-ion capacitors (ZICs) offer inherent advantages for energy storage, yet the role of pore structures in enabling high zinc-ion capacitance remains underexplored. Herein, a dual-molten-salt regulation strategy is employed to derive N/O/S-doped porous carbon nanomaterials, achieving a high specific surface area (SSA) of 2523 m<sup>2</sup>&#xa0;g<sup>−1</sup> with ultramicropores (&lt; 0.86&#xa0;nm) contributing 30.6% of the total SSA. Structural analyses reveal that increasing molten FeCl<sub>3</sub> content yields materials with comparable heteroatom contents and defect structures, but a progressive shift from ultramicropores to mesopores. Crucially, the individual contributions of the pore structure are decoupled by both in situ characterizations and theoretical simulations: The ultramicropores facilitate the desolvation of [Zn(H<sub>2</sub>O)<sub>6</sub>]<sup>2+</sup> (ultramicropore effect), while the hierarchical pores ensure rapid ion transport (hierarchical pore effect). The optimized HHPC-2 delivers a high specific capacitance of 222.6&#xa0;F&#xa0;g<sup>−1</sup> at 1&#xa0;A&#xa0;g<sup>−1</sup> and an energy density of 120.0&#xa0;Wh&#xa0;kg<sup>−1</sup> in ZICs. Intriguingly, its outstanding oxygen reduction reaction catalytic activity enables self-charging upon air exposure after a full discharge, achieving a self-charging rate of 15&#xa0;mAh&#xa0;g<sup>−1</sup>&#xa0;h<sup>−1</sup> and recovering 80% of the externally charged capacity in subsequent discharge cycles. This positions the device as highly promising for practical deployment in regions with intermittent grid power supplies.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Synergistic Ultramicropore and Hierarchical Pore Engineering in Heteroatom-Doped Carbon for High-Performance Zinc-Ion Capacitors

  • Jiale Zhang,
  • Ruifang Zhang,
  • Yangbo Du,
  • Shuaihua Zhang,
  • Runze Gao,
  • Xuanqi Huang,
  • Qi Yang,
  • Debin Kong,
  • Zhichang Xiao

摘要

Carbonaceous zinc-ion capacitors (ZICs) offer inherent advantages for energy storage, yet the role of pore structures in enabling high zinc-ion capacitance remains underexplored. Herein, a dual-molten-salt regulation strategy is employed to derive N/O/S-doped porous carbon nanomaterials, achieving a high specific surface area (SSA) of 2523 m2 g−1 with ultramicropores (< 0.86 nm) contributing 30.6% of the total SSA. Structural analyses reveal that increasing molten FeCl3 content yields materials with comparable heteroatom contents and defect structures, but a progressive shift from ultramicropores to mesopores. Crucially, the individual contributions of the pore structure are decoupled by both in situ characterizations and theoretical simulations: The ultramicropores facilitate the desolvation of [Zn(H2O)6]2+ (ultramicropore effect), while the hierarchical pores ensure rapid ion transport (hierarchical pore effect). The optimized HHPC-2 delivers a high specific capacitance of 222.6 F g−1 at 1 A g−1 and an energy density of 120.0 Wh kg−1 in ZICs. Intriguingly, its outstanding oxygen reduction reaction catalytic activity enables self-charging upon air exposure after a full discharge, achieving a self-charging rate of 15 mAh g−1 h−1 and recovering 80% of the externally charged capacity in subsequent discharge cycles. This positions the device as highly promising for practical deployment in regions with intermittent grid power supplies.