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A Self-Constructed Mg 2+ /K + Co-Doped Prussian Blue with Superior Cycling Stability Enabled by Enhanced Coulombic Attraction.

Zheng XuFengqin ChenYinda LiYunhao LuAijun ZhouJicheng JiangXiongwen XuJian TuBin PanFang ChenYi HuangXinbing ZhaoJian Xie
Published in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2024)
Prussian blue (PB) is regarded as a promising cathode for sodium-ion batteries because of its sustainable precursor elements (e.g., Mn, Fe), easy preparation, and unique framework structure. However, the unstable structure and inherent crystal H 2 O restrain its practical application. For this purpose, a self-constructed trace Mg 2+ /K + co-doped PB prepared via a sea-water-mediated method is proposed to address this problem. The Mg 2+ /K + co-doping in the Na sites of PB is permitted by both thermodynamics and kinetics factors when synthesized in sea water. The results reveal that the introduced Mg 2+ and K + are immovable in the PB lattices and can form stronger K‒N and Mg‒N Coulombic attraction to relieve phase transition and element dissolution. Besides, the Mg 2+ /K + co-doping can reduce defect and H 2 O contents. As a result, the PB prepared in sea water exhibits an extremely long cycle life (80.1% retention after 2400 cycles) and superior rate capability (90.4% capacity retention at 20 C relative to that at 0.1 C). To address its practical applications, a sodium salts recycling strategy is proposed to greatly reduce the PB production cost. This work provides a self-constructed Mg 2+ /K + co-doped high-performance PB at a low preparation cost for sustainable, large-scale energy storage.
Keyphrases
  • heavy metals
  • aqueous solution
  • quantum dots
  • wastewater treatment
  • risk assessment
  • ion batteries
  • metal organic framework
  • single cell
  • visible light
  • gold nanoparticles
  • high intensity