THE EFFECT OF CARBON NANOTUBE ADDITION ON NICKEL SULFIDE (NIS) MATERIALS FOR SUPERCAPACITOR AND ZINC ION BATTERY APPLICATION
The increasing demand in energy drives the development of energy storage devices with high energy capacity and high energy throughput. Supercapacitors are energy storage devices that store charge on their surfaces, providing much greater power density compared to batteries as well as better cycle...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/80407 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The increasing demand in energy drives the development of energy storage devices
with high energy capacity and high energy throughput. Supercapacitors are energy
storage devices that store charge on their surfaces, providing much greater power
density compared to batteries as well as better cycle stability. Pseudocapacitors, as
one type of supercapacitor, utilize the principle of surface redox reaction, providing
better capacitance. One class of materials that has a pseudocapacitor principle is
the transition metal sulfide which exhibit pseudocapacitive behavior owing to their
high redox activity and reaction stability, with nickel sulfide as an example of a
material capable of achieving high capacitance. On the other hand, zinc ion
batteries have emerged as a developing battery technology recently due to their
cost-effectiveness and environmental friendliness, where transition metal sulfides
may become suitable materials for application as cathodes. Unfortunately, the low
conductivity in the redox-based material impairs their capacitance performance at
high currents and at a large number of cycles. Nanostructuring and addition of
conductive materials are believed to improve the performance of pseudocapacitors.
In this study, nickel sulfide material as a pseudocapacitor was composited with
Carbon nanotubes (CNT) using the hot-injection method to demonstrate
experimentally the effect of adding conductive material in enhancing the
pseudocapacitor performance. The first step was to synthesize nickel sulfide without
the addition of CNT and investigate its crystal structure and electrochemical
properties. The results of X-ray Diffraction (XRD) characterization revealed the
formation of a mixed phase of Ni3S2 and NiO. Furthermore, the Cyclic Voltammetry
(CV) characterization of nickel sulfide samples deposited as supercapacitor
electrodes and measured using a three-electrode setup show that there is a redox
reaction, confirming the pseudocapacitive behavior of nickel sulfide. Based on the
results of the Galvanostatic Charge-Discharge (GCD) characterization, the
capacitance of the nickel sulfide sample was obtained at 794,06 F/g.
Next, we added CNTs in a similar synthesis process with compositions of 10, 20,
and 30wt% to determine the optimal composition of CNTs which were then
deposited as electrodes and tested in a three-electrode setup. The CV characterization results still showed the presence of redox peaks, indicating the
pseudocapacitance contributions in the NiS/CNT composite samples. Subsequently,
the GCD characterization showed that the 20wt% NiS/CNT composition showed an
increased charging-discharging time and through capacitance calculations it was
proven that the sample had the highest capacitance of 1249,90 F/g, with a cycle
stability of 94.14% at a current density of 3 A/g over 1500 cycles. Electrochemical
impedance spectroscopy (EIS) characterization demonstrated enhanced charge
transfer ease on the NiS electrode along with the addition of CNT as a conductive
material. The NiS/CNT 20wt% sample, whick demonstrated the best performance,
was then structurally analyzed. The results of the XRD characterization showed the
involvement of carbon originating from CNT in the sample, as evidenced by the
appearance of the (002) peak associated with carbon alongside others
corresponding to Ni3S2 and NiO peaks. SEM characterization showed an irregular
coral-like surface morphology with CNT decoration on part of its surfaces. As a
zinc ion battery cathode, the NiS/CNT 20wt% demonstrated a specific capacity of
132.68 mAh/g, with an energy density of 204.20 Wh/kg at a power density of 1.89
W/kg.
Based on the conducted research, it was found that the addition of CNT in general
can enhance the performance of nickel sulfide pseudocapacitors. This is indicated
by the increase in the capacitance value, with the highest improvement achieved by
the NiS/CNT 20wt% sample. This research should be developed further by
investigating reaction mechanisms with more advanced characterization and
advancing supercapacitor and zinc ion batteries system into more applicable forms.
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