Equimolar bimetallic vanadium titanium based Prussian blue analogue as zero strain cathode for sodium ion batteries

Equimolar bimetallic vanadium titanium based Prussian blue analogue as zero strain cathode for sodium ion batteries

Prussian blue analogues (PBAs) are attractive cathode materials for sodium-ion batteries because of their open framework, rapid ion transport, and low-cost aqueous synthesis; however, electrochemical performance is often limited by defect/water chemistry and the associated structural instability dur...

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Main Authors: Javed, Omama, Mehek, Rimsha, Ali, Ghulam, Radhiyah, Abd Aziz
Format: Article
Language:en
Published: Elsevier 2025
Subjects:
T Technology (General)
TK Electrical engineering. Electronics Nuclear engineering
Online Access:https://umpir.ump.edu.my/id/eprint/46703/1/1-s2.0-S1572665725008495-main.pdf
https://doi.org/10.1016/j.jelechem.2025.119775
https://umpir.ump.edu.my/id/eprint/46703/
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Summary:Prussian blue analogues (PBAs) are attractive cathode materials for sodium-ion batteries because of their open framework, rapid ion transport, and low-cost aqueous synthesis; however, electrochemical performance is often limited by defect/water chemistry and the associated structural instability during cycling. Here, we report an equimolar bimetallic titanium/vanadium PBA, Na₂Ti₀.₅V₀.₅[Fe(CN)₆], synthesized by a simple solution precipitation route and systematically compared with non-equimolar Ti/V analogues prepared under identical conditions. X-ray diffraction confirms a single-phase cubic framework (Fm3‾m). In non-aqueous Na half-cells (2.0–4.5 V vs. Na/Na+), Na₂Ti₀.₅V₀.₅[Fe(CN)₆] delivers an initial discharge capacity of 68.7 mAh g− 1 at 0.1C and retains 62.35 mAh g− 1 after 200 cycles (≈90.8 % retention) with near-unity Coulombic efficiency. Rate capability (0.1C → 10C → 1C) shows stable capacity at high rates and clear recovery on returning to lower current. Electroanalytical measurements indicate favorable kinetics: EIS reveals reduced charge-transfer resistance for the equimolar composition, and CV scan-rate analysis yields an apparent Na+ diffusion coefficient of 2.33 × 10− 8 cm2 s − 1 . In situ XRD demonstrates single-phase Na+ (de)insertion with highly reversible lattice breathing; quantitative lattice-parameter tracking gives a maximum volumetric strain of ~0.07 %, supporting a near-zero-strain mechanism. TGA confirms reduced water content for the equimolar material, consistent with its enhanced phase stability.

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