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Yan Song

Yan Song

Institute of Coal Chemistry, China

Title: Porous worm-like NiMoO4 coaxially decorated electrospun carbon nanofiber as binder-free high performance electrodes for supercapacitors and lithium-ion batteries

Biography

Biography: Yan Song

Abstract

Recently,  various  nanoscale  NiMoO4  structureshave been synthesized and evaluated as electrode materials in both SCs and LIBs due to the relatively low cost, abundant availability, environmental benignity and inherent electrochemical advantages. Given the NiMoO4 prepared in these works exhibits small surface area and dense structure, which impedes the fast ions transport and makes it difficult to alleviate the volume change. Therefore, it will be of great significance to grow porous NiMoO4 nanostructure directly on flexible substrates for effective energy storage. As another carbon textile, electrospun carbon Nano fibers (ECNFs) exhibit smaller diameter and lighter mass when compared with conventional carbon cloth, which is favorable to increase  the  loading  of  NiMoO4,  shorten ion/electron transport pathways and improve the utilization of NiMoO4. The peculiar architectures consisting  of  electrospun  carbon  nanofibers coaxially decorated by porous worm-like NiMoO4 were successfully fabricated for the first time to address the poor cycling stability and inferior rate capability of state-of-the-art NiMoO4-based electrodes. The porous worm-like structure endows the electrode high capacitance/capacity due to large specific surface area and short electron/ion diffusion channels. Moreover, the robust integrated electrode with  sufficient  internal  spaces  can  self- accommodate volume variance during charge/discharge processes, which is beneficial to the structural stability and integrity. By the virtue of rational design of the architecture, the hybrid electrode  delivered  high  specific  capacitance (1088.5 F g-1 at 1 A g-1), good rate capability (860.3 F  g-1    at  20  A  g-1)  and  long  lifespan  (73.9% capacitance retention after 5000 cycles at 10 A g-1) when applied as supercapacitor electrode. For lithium-ion  battery  application,  the  electrode exhibited a high reversible capacity of 689.7 mAh g-1 even  after  150  continuous  cycles  at  a  current density of 1 A g-1.