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PVDF-HFP@Nafion-based quasisolid polymer electrolyte for high migration number in working rechargeable Na-O 2 batteries.

Xin HeYouxuan NiWenjiao MaQiu ZhangZhenkun HaoYunpeng HouHaixia LiZhenhua YanKai ZhangJun Chen
Published in: Proceedings of the National Academy of Sciences of the United States of America (2024)
Rechargeable sodium-oxygen (Na-O 2 ) battery is deemed as a promising high-energy storage device due to the abundant sodium resources and high theoretical energy density (1,108 Wh kg -1 ). A series of quasisolid electrolytes are constantly being designed to restrain the dendrites growth, the volatile and leaking risks of liquid electrolytes due to the open system of Na-O 2 batteries. However, the ticklish problem about low operating current density for quasisolid electrolytes still hasn't been conquered. Herein, we report a rechargeable Na-O 2 battery with polyvinylidene fluoride-hexafluoropropylene recombination Nafion (PVDF-HFP@Nafion) based quasisolid polymer electrolyte (QPE) and MXene-based Na anode with gradient sodiophilic structure (M-GSS/Na). QPE displays good flame resistance, locking liquid and hydrophobic properties. The introduction of Nafion can lead to a high Na + migration number ( t Na + = 0.68) by blocking the motion of anion and promote the formation of NaF-rich solid electrolyte interphase, resulting in excellent cycling stability at relatively high current density under quasisolid environment. In the meantime, the M-GSS/Na anode exhibits excellent dendrite inhibition ability and cycling stability. Therefore, with the synergistic effect of QPE and M-GSS/Na, constructed Na-O 2 batteries run more stably and exhibit a low potential gap (0.166 V) after an initial 80 cycles at 1,000 mA g -1 and 1,000 mAh g -1 . This work provides the reference basis for building quasisolid state Na-O 2 batteries with long-term cycling stability.
Keyphrases
  • ionic liquid
  • solid state
  • pet ct
  • dna repair
  • gas chromatography