PREPARATION AND CHARACTERIZATIONS OF STARCHâN-HEPTYLUREA COMPLEXES AS POTENTIAL MATERIAL FOR CONTROLLED RELEASE FERTILIZER
Urea is a type of fertilizer that contains a high nitrogen content. Nitrogen is required by plants as the main component for the formation of chlorophyll, protein, and amino acids. However, plants are not able to absorb nitrogen from urea optimally, due to the absorption process occurring over...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/83051 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Urea is a type of fertilizer that contains a high nitrogen content. Nitrogen is required
by plants as the main component for the formation of chlorophyll, protein, and amino
acids. However, plants are not able to absorb nitrogen from urea optimally, due to the
absorption process occurring over 2–3 days, and only about 20–30% (w/w) of the
decomposed nitrogen can be absorbed. Moreover, urea is easily decomposed and
easily carried away by rainwater. This leads to the inefficient use of urea fertilizer and
posible to pollute soil and water. One way to address this issue is to modify urea into
an inclusion complex to produce fertilizer with more controlled nitrogen release, also
known as controlled release fertilizer (CRF). In this research, starch was used as the
host molecule. Starch consists of amylose structures in the form of single helices,
having internal cavities. These cavities or channels can be filled with urea based
fertilizers. First, hydrophobicity of urea needs to be increased. Unmodified urea that is
hydrophilic cannot directly interact with hydrophobic amylose cavities. Urea was
reacted with 1-bromoheptane to form an urea derivative with one hydrogen substituted
by heptyl (N-hepthylurea). N-heptylurea was characterized using fourier transform
infrared (FTIR), nuclear magnetic resonance (NMR), X-ray diffraction (XRD), and
thermogravimetric analysis (TGA). Then, N-heptylurea was mixed with starch
solution to form starch–N-heptylurea inclusion complexes. Starch–N-heptylurea
complexes were characterized using FTIR and XRD, and an iodine test. IR, NMR, and
XRD characterization results indicated that N-heptylurea was successfully formed
with a yield of 2.5% (w/w). N-heptylurea product was complexed with starch to
produce starch–N-heptylurea complexes. The percentage of N-heptylurea as the guest
molecule was varied at 5% (w/w) and 7% (w/w) based on the complex mass. The
characterization and iodine test results showed that the starch–N-heptylurea inclusion
complexes were successfully formed, with complexation percentages of 74% (w/w)
for both 5% and 7% guest molecule variation. The study of nitrogen release was
conducted for urea, N-heptylurea, and starch–N-heptylurea complexes 5% and 7%
guest molecule variation. On 4 days after planting, accumulative nitrogen (in form of
NH4+ and NO3–) released from N-heptylurea and starch–N-heptylurea was slower
compared to the nitrogen release from urea. This trend also seen on 10 days after
planting, but the accumulative nitrogen released was higher than on 4 days after
planting. The study of nitrogen release showed that starch–N-heptylurea complexes
can indeed slow down the nitrogen release from urea fertilizers. |
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