Photo by sndrx from unsplash
In this work, mesoporous hollow SiC nanospheres (MHS-SiC) are successfully fabricated via in situ magnesiothermic reduction of mesoporous hollow carbon-silica nanospheres (MHS-SiO2/C), which inherit a unique interconnected network on the… Click to show full abstract
In this work, mesoporous hollow SiC nanospheres (MHS-SiC) are successfully fabricated via in situ magnesiothermic reduction of mesoporous hollow carbon-silica nanospheres (MHS-SiO2/C), which inherit a unique interconnected network on the shell. The specially designed interpenetrating shell structure provides an accessible interface between Si and C elements in a confined nanospace during magnesiothermic reduction, and thus well-dispersed MHS-SiC nanospheres (∼95 nm in diameter) with interconnected mesoporous shells and high specific surface area (868 m2 g-1) can be obtained. For practical applications, the obtained MHS-SiC electrode exhibits a high-rate capacitance and long cycling stability for supercapacitors.
Journal Title: Chemical communications
Year Published: 2022
Link to full text (if available)
Share on Social Media: Sign Up to like & get
recommendations!