Three-dimensional hierarchical porous Na3V2(PO4)3/C structure with high rate capability and cycling stability for sodium-ion batteries

“…Another efficient method to construct hierarchically structured porous NVP microflowers is to employ surfactants (e. g., sodium oleate, oleic acid, hexadecyltrimethylammonium bromide, and sodium dodecyl sulfonate) as the structuredirecting agent, which can regulate the nucleation and growth process of NVP precursor to form the primary nanoflake-like precursors. [43][44][45][46][47] The evolution mechanism from the nanoflakelike precursors to hierarchical microflowers conforms to the Ostwald ripening process. Cao et al, [43] developed a solid-state reaction approach to synthesize the 3D graphene decorated NVP nanoflakes (NVP-NFs) using paraffin wax as the nonpolar solvent and oleic acid as the structure-directing agent.…”

The Synthesis of Porous Na₃V₂(PO₄)₃ for Sodium‐Ion Storage

“…Another efficient method to construct hierarchically structured porous NVP microflowers is to employ surfactants (e. g., sodium oleate, oleic acid, hexadecyltrimethylammonium bromide, and sodium dodecyl sulfonate) as the structuredirecting agent, which can regulate the nucleation and growth process of NVP precursor to form the primary nanoflake-like precursors. [43][44][45][46][47] The evolution mechanism from the nanoflakelike precursors to hierarchical microflowers conforms to the Ostwald ripening process. Cao et al, [43] developed a solid-state reaction approach to synthesize the 3D graphene decorated NVP nanoflakes (NVP-NFs) using paraffin wax as the nonpolar solvent and oleic acid as the structure-directing agent.…”

The Synthesis of Porous Na₃V₂(PO₄)₃ for Sodium‐Ion Storage

“…In the work, NVP was synthesized by an easy calcination method that can be scaled for large production. Another material with NVP and in situ carbon layers (NVP/C‐T), which develops into a 3D skeleton structure developed by Ling et al, 7 also performs well in high C rates and shows improved stability with a value of 70.1 mAh g −1 at 2C after 200 cycles with a columbic efficiency of 98.6%. Similar to these, various other studies were carried out such as in situ carbon layers combined with NVP giving a 3D skeleton structure, carbon layer combined with nitrogen (N) doped graphene Aerogel (NVP@C/N‐GA), double carbon embedding on NVP (DC‐NVP).…”

“…Similar to these, various other studies were carried out such as in situ carbon layers combined with NVP giving a 3D skeleton structure, carbon layer combined with nitrogen (N) doped graphene Aerogel (NVP@C/N‐GA), double carbon embedding on NVP (DC‐NVP). These works reported improved electrochemical performance, specifically in terms of performance at high C rates and good rate capability 7,85,93 . The carbon sources used in the synthesis were different for each group.…”

“…Electrochemical batteries, with high energy efficiency, flexibility, pollution‐free operation, and ease of maintenance, are considered propitious and excellent sources of energy storage systems 4,6‐8 . Batteries find a wide range of applications in portable electronics, electric vehicles, and complement the renewable sources of power like wind and solar 9 .…”

Utilization of symmetric electrode materials in energy storage application: A review

“…Most of the previous reports on symmetric full cells have focused only on the modication of NVP cathodes. [12][13][14][15] Even though the NVP cathode possesses superior characteristics in terms of the structural stability and reaction mechanism, the material's low electronic conductivity limits its electrochemical performance. 10 Previous studies have tried to overcome this drawback by adopting doping strategies and utilizing conductive carbon matrices.…”

High power Na₃V₂(PO₄)₃ symmetric full cell for sodium-ion batteries