Fe-regulated δ-MnO2 nanosheet assembly on carbon nanofiber under acidic condition for high performance supercapacitor and capacitive deionization

Birnessite-type MnO2 (delta-MnO2) nanosheet assembly with various structures were achieved by redox reaction of KMnO4 under acidic condition with Fe regulation on Fe-doping carbon nanofibers (Fe-CNFs)(.) The Fe-CNFs with various Fe contents were conveniently obtained by carbonization of the electrospun ferric acetylacetonate-polyacrylonitrile (AAI-PAN) fiber with various AAI ratios. X-ray diffraction and transmission electron microscopy demonstrated the formation of delta-MnO2 on the Fe-CNFs. pHs of KMnO4 solution and Fe content in the fiber affected the morphology of delta-MnO2. At pH = 2, the uniform delta-MnO2 nanosheet assembly was transferred into a tubular structure by adjusting Fe content in the Fe-CNFs template (AAI = 5%, mass ratio). The obtained delta-MnO2@Fe-CNF-5% exhibited the highest aspect ratio, large surface area and best charge-transfer behavior. The delta-MnO2@Fe-CNF-5% electrode delivered a specific capacitance of 210 F/g (0.3 A/g) and a superior cycling stability with 94% capacitance retention in 4500 cycles. The delta-MnO2@Fe-CNF-5%, as a negative electrode presented an excellent performance both in supercapacitor with high energy density (20 Wh/kg) and in capacitive deionization cell with the salt adsorption capacity of 20 mg/g. The unique nanostructure and excellent electrochemical performance render the delta-MnO2@Fe-CNF-5% composite as a much promising material for charge storage and deionization applications.

Automated summary

Various structures of Birnessite-type MnO2 (delta-MnO2) nanosheet assembly were achieved via redox reactions of KMnO4 under acidic conditions with Fe regulation on Fe-doping carbon nanofibers (Fe-CNFs). Adjusting the Fe content in the Fe-CNFs template can impact the morphology of delta-MnO2, leading to high specific capacitance and superior cycling stability. The obtained composite of delta-MnO2@Fe-CNF-5% exhibited excellent electrochemical performance, making it a promising material for charge storage and deionization applications.