2018
DOI: 10.1002/cphc.201800070
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Density Functional Theory Calculations of the Quantum Capacitance of Graphene Oxide as a Supercapacitor Electrode

Abstract: Graphene oxide has become an attractive electrode-material candidate for supercapacitors thanks to its higher specific capacitance compared to graphene. The quantum capacitance makes relative contributions to the specific capacitance, which is considered as the major limitation of graphene electrodes, while the quantum capacitance of graphene oxide is rarely concerned. This study explores the quantum capacitance of graphene oxide, which bears epoxy and hydroxyl groups on its basal plane, by employing density f… Show more

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Cited by 58 publications
(33 citation statements)
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“…A hypothesis explains such differences by the transfer of localised and partially or zone-delocalised valence electrons, leading to Nernstian and pseudocapacitive responses, respectively [19]. It agrees with density functional theory modelling of oxygen doped graphenes [20,21]. According to the band model [22], localised valence electrons have a fixed electronic energy level, corresponding to a fixed potential for their transfer.…”
Section: Pseudocapacitance Explainedsupporting
confidence: 72%
“…A hypothesis explains such differences by the transfer of localised and partially or zone-delocalised valence electrons, leading to Nernstian and pseudocapacitive responses, respectively [19]. It agrees with density functional theory modelling of oxygen doped graphenes [20,21]. According to the band model [22], localised valence electrons have a fixed electronic energy level, corresponding to a fixed potential for their transfer.…”
Section: Pseudocapacitance Explainedsupporting
confidence: 72%
“…An effective strategy to construct novel electrode materials with high energy storage density has been illustrated by Li et al, 367 using N-doped graphene quantum dots for high-performance exible supercapacitors. Song et al 368 and many other researchers [369][370][371][372][373][374][375][376][377][378] investigated graphene oxide as a supercapacitor electrode material to study the quantum capacitance by means of DFT studies. These observations may shed light on developing new theoretical models based on DFT studies for the improvement of the energy density of carbon-based supercapacitors.…”
Section: Nanostructured Materials For Advanced Supercapacitorsmentioning
confidence: 99%
“…Activated carbons are the primary choice and are widely used in SCs because of their high surface area and relatively high packing density . However, dramatic degradation in their efficiency at high charge–discharge rates because of the considerable ion-diffusional losses is a major disadvantage, despite the achievement of reasonable specific capacitance in an aqueous electrolyte. , To overcome these problems, nanoscale carbons have been extensively explored as SC electrode materials, but there are a number of drawbacks including undesirable capacitance loss during rapid charging–discharging. , Furthermore, their low energy density (typically in the range of 5–20 Wh kg –1 ), low power density, and poor cycle stability in organic/ionic liquid electrolytes are substantial obstacles to their compensation to batteries. , A well-designed carbon-based material with high surface area, good electrical conductivity, and enhanced ion diffusion kinetics could be expected to boost the specific energy of SCs …”
Section: Introductionmentioning
confidence: 99%