Insight into the Evolution of Voids at the NASICON/Na Interface and Suppressing Void Accumulation by a Semiliquid Wetting Strategy

Abstract: NASICON-based solid-state batteries have attracted much attention due to their high safety and high energy density. However, the unstable interface contact usually leads to sodium dendrite formation and cell failure during cycling. Deep insights into the evolution of the NASICON/Na interface are conducive to designing a morphologically stable interface. Herein, for the first time, we develop an asymmetric stripping/plating method to investigate the evolution process of the NASICON/Na interface via a facile two… Show more

“…Up to now, many attempts have been made to create intimate interfacial contact between Na anode and NZSP electrolyte, such as introducing a sodiophilic modification layer, ,− decomposing surface impurities, , and ultrasonic welding. , These approaches have made significant progress in enhancing the interface of Na anode with NZSP electrolyte (interfacial impedance <10 Ω cm 2 ), but the symmetric cells can only be operated at lower current densities (0.05–0.3 mA cm –2 ) for shorter periods (400–1500 h). The main reason for this is that such methods of enhancing the Na|electrolyte interface contact can only improve the transport of Na across the solid Na|NZSP interface but cannot accelerate the migration rate of Na from bulk to interface, which will cause the voids and pores to be formed again at the interface during the speedy Na stripping operation.…”

Stabilized Solid–Solid Interface for Solid-State Sodium Batteries Using Gradient Ion-Electron Conductive Phases Modified Sodium Metal Anode

“…Up to now, many attempts have been made to create intimate interfacial contact between Na anode and NZSP electrolyte, such as introducing a sodiophilic modification layer, ,− decomposing surface impurities, , and ultrasonic welding. , These approaches have made significant progress in enhancing the interface of Na anode with NZSP electrolyte (interfacial impedance <10 Ω cm 2 ), but the symmetric cells can only be operated at lower current densities (0.05–0.3 mA cm –2 ) for shorter periods (400–1500 h). The main reason for this is that such methods of enhancing the Na|electrolyte interface contact can only improve the transport of Na across the solid Na|NZSP interface but cannot accelerate the migration rate of Na from bulk to interface, which will cause the voids and pores to be formed again at the interface during the speedy Na stripping operation.…”

Stabilized Solid–Solid Interface for Solid-State Sodium Batteries Using Gradient Ion-Electron Conductive Phases Modified Sodium Metal Anode

High current and dendrite-tolerant NaF/ZnO coated Na3Zr2Si2PO12 electrolyte prepared by a facile spraying method

Na vs. Li metal anodes for batteries: unraveling thermodynamic and electronic origins of voids and developing descriptors for artificial surface coatings