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Effects of Sodium Vacancies and Concentrations in Na 3 SO 4 F Solid Electrolyte.

Xue WangXuele XuYuxiang LiWenqian ChenGuowei ZhaoHeng WangYa TangPengcheng WuLiang Tang
Published in: ACS omega (2024)
The sodium-rich solid electrolyte, Na 3 SO 4 F (NSOF), holds promise for eco-friendly and resource-abundant energy storage. While the introduction of heterovalent dopants has the potential to enhance its suitability for battery applications by creating Na vacancies, the effect of vacancies and sodium concentrations on sodium conduction remains unclear. In this work, Mg 2+ was introduced into Na + sites in Na 3 SO 4 F, generating sodium vacancies with different contents by using solid-state synthesis method. Among the resulting materials, Na 2.96 Mg 0.02 SO 4 F exhibited an ionic conductivity that is two-order-of-magnitude higher than NSOF at 298 K. Notably, as the sodium concentration decreased, the ionic conductivity also declined, revealing an equilibrium between Na vacancies and concentrations. To further investigate the influence of sodium concentration, excess Na + was introduced into NaMgSO 4 F, which inherently possesses a lower sodium content by using solid-state synthesis method. However, this adjustment only led to an approximately one-order-of-magnitude enhancement in optimal ionic conductivity at 298 K. Combined with an in situ X-ray diffraction analysis, our findings underscore the greater sensitivity of sodium conduction to variations in sodium vacancies. This study paves the way for the development of ultrafast sodium ion conductors, offering exciting prospects for advanced energy storage solutions.
Keyphrases
  • solid state
  • ionic liquid
  • magnetic resonance imaging
  • high resolution
  • artificial intelligence
  • human health
  • crystal structure