H. K. Shahzad, Zhengri Huang, Sasan Ghashghaie, Han Liu, G. Muhyodin, Mohsen Tamtaji, Hoi Lam Li, F. Chuan Chan and C. Y. Chung
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引用次数: 0
Abstract
Two-dimensional metallic vanadium disulfide (VS2) has gained significant attention due to its excellent electrical and electrochemical properties, making it a promising candidate for energy storage and electronic applications. Despite the advantages of hydrothermal synthesis in producing VS2 nanosheets, the underlying reaction pathways and critical synthesis parameters remain insufficiently understood. This study presents a systematic investigation of the key reaction variables influencing the hydrothermal growth of hierarchical VS2 nanosheets on a three-dimensional substrate. By optimizing precursors' (NH4VO3 : TAA) molar ratios, reaction temperature, time, and ammonia concentration, we achieved precise control over the morphology and phase of VS2. Our findings demonstrate that pure VS2 nanosheets can be synthesized in just 5 hours, significantly reducing the conventional reaction time of 20 hours while maintaining phase purity and structural integrity. The parametric insights provided in this study establish a robust foundation for designing tunable VS2 architectures with potential applications in catalysis, sensors, hydrogen evolution, and next-generation energy storage devices.
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