Electrochemical Study of Graphene Coated Nickel Foam as an Anode for Lithium-Ion Battery

Carbon fabric is proposed as the electrode support instead of Cu foil as the current collector in the fabrication of Si-anode, in order to prevent electrode pulverization during cell charge/discharge. Polyvinylpyrrolidone is used as a suitable dispersant to improve the anode slurry’s compatibility with the carbon fabric and final uniform distribution of the anode materials. The anode with added dispersant exhibits a lower resistance, and the constructed cell presents a higher capacity than that without dispersant in the anode (3561 vs 2755 mAh g−1) in the first charge/discharge cycle under a current of 420 mA g−1. After charge/discharge for 150 cycles, the stress from repeated formation/deformation of the solid-electrolyte interface layer only breaks a part of the fibers in the carbon fabric, while acceptable structural integrity is maintained in the anode. Interestingly, the added dispersant enhances both the uniform distribution of nano-Si electrode materials and the anode’s conductivity, while diminishing the fabric damage during charge/discharge cycles. This is attributed to the smaller, well-deagglomerated nano-Si particles that are better at sustaining the stress caused by cell charge/discharge, and also the binding force from the dispersant to reinforce the carbon fabric.

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“…1), and the latter is related to further delithiation of Li (x-y) Si to amorphous Si (a-Si) at higher potential (Eq. 2): 30,31…”

Section: Resultsmentioning

confidence: 99%

Good Structural Stability of Si Anodes Achieved through Dispersant Addition and Use of Carbon Fabric as Conductive Framework

Cho

Chen

et al. 2021

J. Electrochem. Soc.

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“…In addition, Mukanova et al 41 reported graphene (GF) thin film on NiO‐Ni foam by CVD technique and investigated its electrochemical performance as anode for LIBs. The 3D GF coated NiO‐Ni anode exhibited a gradual increase of its areal charge capacity from 65 μAh cm −2 at the initial cycle to 250 μAh cm −2 at the final 250th cycle.…”

Section: Binder Free Porous Nio‐ni Foam As Anode Of Libsmentioning

confidence: 99%

A review on binder‐free NiO‐Ni foam as anode of high performance lithium‐ion batteries

Rahman

Song

2021

Energy Storage

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In recent times, lithium-ion batteries (LIBs) are widely used in the fields of small electronic devices, wearable electronic devices, and automobiles. In the light of some current research on LIBs investigated on replacing commercial carbonaceous anode materials with transition metal oxides such as NiO due to its high theoretical capacity of 718 mAh g À1 . However, NiO still suffers from low cycling stability, low coulombic efficiency, and low rate capability resulting from large volume expansion and poor electrical conductivity which greatly limits the development of large-capacity LIBs. To overcome these barriers, various NiO electrodes with different morphologies and physical structures are developed. In this review, we introduce and summarize the electrochemical performances of binder-free NiO-Ni foam as anode of LIBs.

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Synergistic degradation of GenX (hexafluoropropylene oxide dimer acid) by pairing graphene-coated Ni-foam and boron doped diamond electrodes

Olvera‐Vargas

Wang

et al. 2022

Chemical Engineering Journal

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Electrochemical Study of Graphene Coated Nickel Foam as an Anode for Lithium-Ion Battery

Cited by 5 publications

References 32 publications

Good Structural Stability of Si Anodes Achieved through Dispersant Addition and Use of Carbon Fabric as Conductive Framework

Good Structural Stability of Si Anodes Achieved through Dispersant Addition and Use of Carbon Fabric as Conductive Framework

A review on binder‐free NiO‐Ni foam as anode of high performance lithium‐ion batteries

Synergistic degradation of GenX (hexafluoropropylene oxide dimer acid) by pairing graphene-coated Ni-foam and boron doped diamond electrodes

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