PHOTOCATALYTIC CONVERSION OF CO2 TO METHANOL USING CUO-ZNO Z-SCHEME HETEROJUNCTION PHOTOCATALYST FROM ZNC BATTERY WASTE
Carbon dioxide (CO2) as the main contributor of anthropogenic greenhouse gas emissions creates an urgency in developing a solution in mitigating the excess release of carbon into the atmosphere and preventing the ever-worsening climate change. A photocatalytic process of converting CO2 into metha...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/82016 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Carbon dioxide (CO2) as the main contributor of anthropogenic greenhouse gas emissions
creates an urgency in developing a solution in mitigating the excess release of carbon into
the atmosphere and preventing the ever-worsening climate change. A photocatalytic
process of converting CO2 into methanol using ZnO-CuO z-scheme nanocomposite
photocatalyst is proven to be effective with usage of battery waste. The ZnO-CuO
nanocomposites with several loading variations of 2.5, 5, 7.5, and 10 %-mol were
successfully synthesized through a co-precipitation method. The ZnO photocatalyst from
ZnC battery waste was also successfully synthesized using hydrometallurgical method.
An optimum loading of the battery waste-based catalyst was also synthesized at 5%-mol
according to photocatalyst characterization results.
XRD analysis shows a successful formation of all photocatalysts with a crystal structure
analysis due to peak shifts, crystallinity, and average crystalline sizes. SEM results
showed the morphological changes of the photocatalyst in respect to the loading. UV-Vis
DRS displays an increased absorbance in the visible light region wavelength and
decreased band-gap in respect towards CuO loading increase. The visible light region
absorbance of the ZnO photocatalyst created from battery waste was proven to be higher
than the commercial precursor. N2 Isotherm (BET-BJH method) was able to ascertain that
all photocatalysts are mesopores with H3 hysteresis type with varying surface area, pore
volume, pore diameter, and pore size distribution. The activity test has shown that
compared to all photocatalysts variation, the 5% CuO-ZnO from battery waste has the
highest methanol yield. The high production rate and kinetics can be analyzed statistically,
the suggested scheme is a z-scheme mechanism. The 2-way interaction of the pH of the
environment and loading of the ZnO, also both pH and loading independently affects the
methanol production by photocatalytic conversion while the source of the photocatalyst
does not (i.e. battery or commercial), this leads to the conclusion that battery waste based
photocatalyst may produce comparable results or even better. |
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