Uncovering the Fundamental Role of Interlayer Water in Charge Storage for Bilayered V2O5•nH2O Xerogel Cathode Materials

Interlayer engineering is a promising strategy to modify the structure of layered vanadium-based oxides with optimized ion-diffusion capability, during which the role of interlayer crystal water in tuning the charge storage properties should be clarified. Herein, a series of hydrated V2O5 center dot nH(2)O xerogels with varying contents of interlayer water (n) is obtained by differentiating the temperature parameter. Results show that the value n should be properly modified to the best value that is not too large or too small, that is, when n equals 0.26, the V2O5 center dot nH(2)O electrode exhibits optimized discharge capacity (456.5 mAh g(-1) at 0.1 A g(-1)) and cycling stability with 94.3% retention after 2,000 cycles at 3 A g(-1). Regulation of interlayer water content appears to weaken the electrostatic interaction between the V-O framework and intercalated Zn2+, which thus enhances the reversibility of the zincation and structural evolution during cycling. Density functional theory calculations suggest that the V2O5 center dot nH(2)O material with modulated electron structure can provide a favorable electrostatic environment for reversible Zn2+ diffusion with a lower migration barrier. The findings of this work are expected to arouse more intensive research efforts into the role of structural water in tuning the energy storage performance in various electrode materials.

Automated summary

Interlayer engineering is a promising strategy to modify the structure of layered vanadium-based oxides for optimized ion-diffusion capability. This study explores the role of interlayer crystal water in tuning the charge storage properties and finds that regulating interlayer water content can enhance the reversibility of zinc ion diffusion and improve the cycling stability of V2O5·nH2O electrodes. Density functional theory calculations suggest that modulated electron structure in V2O5·nH2O materials provides a favorable electrostatic environment for reversible Zn2+ diffusion.