Rational Fabrication and Improved Lithium Ion Battery Performances of Carbon Nanofibers Incorporated with α-Fe2O3 Hollow Nanoballs

Abstract

The present results contribute a facile route to prepare carbon nanofibers hybrided with hollow metal oxide nanoparticles under the assistance of Kirkendall effect. α‒Fe2O3 hollow nanoball incorporated carbon nanofibers (denoted as FOCNFs) are rationally fabricated by using electrospun composite carbon nanofibers (CNFs) as the precursors. The hollow nanoparticles are 69.8 nm in the average size with the shell thickness of 14 nm. The composite nanofibers are hierarchically porous. The mesopores are in the range of 2 ‒ 10 nm and center at 3.7 nm. The micropores center at 0.5 nm with the micropore volume of 0.02 cm3·g−1. Time dependant morphology evolutions confirm that the formation of α‒Fe2O3 hollow nanoballs is promoted by the nanoscale Kirkendall effect due to the migration difference between oxygen molecules and Fe3+ cations in the solid. This route is also successfully extended to fabricate hollow Co3O4 and NiO nanoparticles incorporated carbon nanofibers. FOCNFs exhibit improved lithium ion battery performances with enhanced capacity, rate capability and long-term cycling stability. The optimized sample of FOCNFs‒30 delivers a high initial capacitance of 1903.8 mAh·g-1 at 100 mA·g-1. A reversible capacity of 601.2 mAh·g-1 sustains at 0.1 C after 300 charge-discharge cycles. The improved electrochemical performances of FOCNFs stem from coupling the characteristics of α-Fe2O3 nanoballs and porous nanofibrous carbon matrix.