DEVELOPMENT OF ACTIVATED CARBON FROM TREMBESI SEEDS AS AN ADSORBENT FOR CHROMIUM HEAVY METAL
One of the negative impacts of the textile industry is the metal waste produced from the dyeing process, such as chromium, which can damage ecosystems and the health of living organisms. Therefore, metal waste treatment is needed, one method being adsorption. To enhance the use of biomass, heavy...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/81868 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | One of the negative impacts of the textile industry is the metal waste produced from the
dyeing process, such as chromium, which can damage ecosystems and the health of living
organisms. Therefore, metal waste treatment is needed, one method being adsorption. To
enhance the use of biomass, heavy metal adsorption can be carried out using biomassbased
adsorbents, such as monkeypod seeds. This study aims to create an adsorbent from
monkeypod seeds for chromium adsorption and to determine the adsorption parameters
that provide the best adsorption performance. The stages of this research include
adsorbent preparation, adsorption testing, adsorption performance determination, and
adsorbent characterization. Activated carbon, made through carbonization and activation
processes, will form activated carbon that can be used as an adsorbent. The adsorbent is
tested by contacting it with a chromium solution in a beaker batch-wise, then calculating
the adsorption percentage and adsorbent capacity. Adsorbent characterization includes
surface area and morphology, as well as adsorbent functional groups. The adsorption
parameters varied include carbonization temperature (200-600°C and without
carbonization), types of activators (HCl, H3PO4, and NH4Cl, each at 1 M), feed
concentration (20-40 ppm), contact time (30-120 minutes), and adsorbent concentration
(0,5-1,5 grams per 100 mL of solution). All experiments were conducted at the Bandung
Institute of Technology Laboratory. The experimental results showed that the optimal
treatment variation for the adsorbent was without carbonization and activation with HCl.
This treatment produced an adsorbent with a surface area of 0,3 m²/gram based on BET
analysis and a highly porous surface morphology according to SEM analysis. Based on
FTIR analysis, the functional groups present on the adsorbent were hydroxyl, methyl,
carbonyl, and nitro groups. The optimal conditions for the chromium metal adsorption
process with the treated adsorbent were a feed concentration of 40 ppm, a contact time of
30 minutes, and an adsorbent concentration of 1 gram/100 mL solution. The most optimal
adsorption process resulted in an adsorption percentage of 49% with an adsorbent
capacity of 2,31 mg Cr/g adsorbent. |
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