N-Doping-Induced Amorphization for Achieving Ultrastable Aqueous Zinc-Ion Batteries.
Yan LiHuibin LiuMingyu MaWenchao PengYang LiXiaobin FanPublished in: ACS applied materials & interfaces (2024)
Vanadium-based oxides, known for their high capacity and low cost, have garnered significant attention as promising cathode candidates in aqueous zinc-ion batteries. Nonetheless, their poor rate performance and limited durability in aqueous electrolytes present a challenge to the realistic implementation of vanadium-based aqueous zinc-ion batteries. Here, we synthesized nitrogen-doped V 2 O 3 @C (N-V 2 O 3 @N-C) via ammonia treatment of V 2 O 3 @C derived from vanadium-based metal-organic framework (V-MOF), aiming to achieve outstanding rate and cycling performance. The N-V 2 O 3 @N-C electrode exhibits notable in situ self-transformation into an amorphous state. Density functional theory calculations reveal that the distorted N-V 2 O 3 structure and uneven charge distribution result in the creation of an amorphous state. As expected, Zn/N-V 2 O 3 @N-C aqueous zinc-ion batteries can achieve remarkable specific capacity (349.0 mAh g -1 at 0.1 A g -1 ), along with impressive rate performance, showcasing a capacity of 253.5 mAh g -1 at 5 A g -1 and exceptional durability at 5 A g -1 (96.4% after 1350 cycles). The employed induced amorphization approach offers novel perspectives for designing high-performance cathodes that exhibit both sturdy structures and extended cycling lifespans.
Keyphrases
- ion batteries
- density functional theory
- ionic liquid
- metal organic framework
- oxide nanoparticles
- low cost
- room temperature
- molecular dynamics
- high glucose
- diabetic rats
- primary care
- healthcare
- high resolution
- high intensity
- gene expression
- genome wide
- single cell
- solid state
- risk assessment
- quality improvement
- heavy metals
- molecular dynamics simulations
- dna methylation
- endothelial cells
- gold nanoparticles