A novel nitrogen/oxygen co-doped carbon sponge (NOCS) is directly applied as a monolithic binder-free electrode for supercapacitors. It exhibits a high specific capacitance and excellent electrochemical cyclability.
Developing
monolithic electrodes with high capacitor performance
remains a challenge in energy storage field. KOH is applied to chemically
activated commercial melamine sponges, and it can prepare monolithic
N-/O-doped carbon sponge (NOCS) electrodes. The graphitization degree,
heteroatom content, and pore size distribution can be regulated by
adjusting the KOH/melamine sponge mass ratio. The optimal electrode
demonstrates specific capacitances of 440 F g–1 at
1.0 mV s–1 and 273 F g–1 at 0.5
A g–1, and the capacitance retention remains 85.0%
after 10,000 charging–discharging cycles at 10 A g–1. The charge storage mechanism in NOCSs is systematically studied
by separating the capacitive effect (pseudo-capacitance) from the
diffusion-controlled contribution (electrical double-layer capacitance).
Moreover, the capacitance performances of NOCSs in a polyvinyl alcohol/KOH
electrolyte are also investigated by assembling all-solid-state supercapacitors,
which can output an energy density of 5.61 W h kg–1 at 250 W kg–1 and power three light-emitting diodes
with different colors.
Monolithic electrodes show a great advantage in energy storage devices. Nitrogen/oxygen co-doped carbons sponges (NOCSs) prepared from carbonized melamine foams are directly applied as the supercapacitor electrodes without any additives and binders. The influence of carbonization temperatures from 650 to 950°C on the heteroatom (N and O) content, surface area, graphitization degree, and capacitor performance of carbon sponges are systematically investigated, and it is found that NOCS-850 delivers a better overall capacitive properties for its balanced heteroatom content, surface area, and graphitization degree. It possess specific capacitances of 338 F g À 1 at a scan rate of 1.0 mV s À 1 and 168.3 F g À 1 at a current density of 0.5 A g À 1 in 1.0 M H 2 SO 4. After 5000 cycles of repeated charging/discharging process, the capacitance retention remains 107%. When being assembled into an all-solid-state supercapacitor, the NOCS-850 has a energy density of 5.38 Wh kg À 1 at a power density of 233 W kg À 1. A red light-emitting diode can be successfully lighted by three connected all-solid-state supercapacitors of NOCS-850, illustrating its potential application in energy storage field.
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