DEVELOPMENT OF TRANSITION METAL SULFIDE NANOPARTICLES FOR ENERGY STORAGE APPLICATION
Energy storage is one of the breakthroughs in this decade, becoming one of the answers to stop global warming through electric vehicle (EV) utilization. Among many energy storage devices, Supercapacitors have risen as an energy storage device as they could provide high-energy density in high-powe...
Saved in:
| Main Author: | |
|---|---|
| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/74330 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Energy storage is one of the breakthroughs in this decade, becoming one of the
answers to stop global warming through electric vehicle (EV) utilization. Among
many energy storage devices, Supercapacitors have risen as an energy storage
device as they could provide high-energy density in high-power density. Through
EDLC and Pseudocapacitors, supercapacitor allows many technologies to use
renewable energy as their sources. However, supercapacitor performance is
dependent on their electrode. Nanoparticle, a nanosized particle with a high
surface-area-to-volume ratio, offers a vast potency to produce a high-energy
supercapacitor. Several breakthrough materials such as Transition Metal Sulfide
(TMS), MXene, Graphene, and Metal Organic Framework has been proven as
high-performance supercapacitor materials. Increasing their performance
through conductive agent cooperation, surface functionalization, and optimizing
their surface is an intriguing solution to their problem. Despite many efforts to
increase the supercapacitor performance, the current energy density status still
needs to be enhanced. However, reducing the TMS size to nanometer scale has
been challenging issues and has not been explored yet. Also, further exploration,
either from experimental or computational work, is still needed. This study
combined the experimental and simulation to answer the need for a higher energy
density supercapacitor. Several simulations based on first-principles study was
utilized to search either new material or a new mechanism to enhance
supercapacitor, i.e., quantum capacitance. The first-principles calculation gives a
guideline for synthesizing high-performance supercapacitors. Dopant role were
rigorously discussed from quantum capacitance and pseudocapacitance
perspectives. From the synthesized process, the TMS synthesize has been proven as good supercapacitor materials. This work gives a new perspective to process
the TMS by directly grow the materials on the electrode. Moreover, this study also
shows that new superstructures called as hierarchical nanopores were able to
utilize TMS nanoparticle full potential. We discovered that this structure was able
to optimize nanoparticle abundance surface area while maintaining structural
integrity to ensure high conductivity of the electrodes. In general, this study's
results also open new avenues to increase the supercapacitor performance by
utilizing the nanoparticle full potential and new mechanisms such as quantum
capacitance modulation |
|---|