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Sains Malaysiana 45(5)(2016): 833–839
Production and Characterization of the Defatted Oil Palm Shell Nanoparticles (Penghasilan
dan Pencirian Nanopartikel Tempurung Kelapa Sawit Ternyah Lemak)
ABDUL KHALIL, H.P.S.1*, MD. SOHRAB HOSSAIN1, NUR AMIRANAJWA, A.S.,1
NURUL FAZITA, M.R.,1 MOHAMAD HAAFIZ, M.K.,1 SURAYA, N.L.M.,1DUNGANI, R.2
& FIZREE, H.M.2
1School of Industrial
Technology, Universiti Sains Malaysia, 11800 Penang, Malaysia
2School of Life Sciences
and Technology, Institut Teknologi Bandung, Gedung Labtex XI, Jalan Ganesha 10,
Bandung 40132, West Java-Indonesia
Diserahkan:
3 April 2015/ Diterima: 2 Disember 2015
ABSTRACT
This present study was conducted to
produce defatted oil palm shell (OPS) nanoparticles. Wherein,
the OPS nanoparticles were defatted by solvent extraction
method. Several analytical methods including transmission electron microscope (TEM),
X-ray diffraction (XRD), particle size analyzer, scanning
electron microscope (SEM), SEM energy
dispersive X-ray (SEM-EDX) and thermal gravimetric
analyzer (TGA) were used to characterize the untreated and defatted OPS nanoparticles. It was found that 75.3% OPS particles
were converted into nanoparticles during ball milling. The obtained OPS nanoparticles
had smaller surface area with angular, irregular and crushed shapes under SEM view.
The defatted OPS nanoparticles did not show any agglomeration during TEM observation.
However, the untreated OPS nanoparticles had higher
decomposition temperature as compared to the defatted OPS nanoparticles.
Based on the characterization results of the OPS nanoparticles,
it is evident that the defatted OPS nanoparticles has the
potentiality to be used as filler in biocomposites.
Keywords: Composite materials;
nanofiller; nanoparticles; oil extraction; oil palm shell; solvent extraction
ABSTRAK
Kajian ini
telah dijalankan untuk menghasil dan mencirikan partikel nano tempurung kelapa
sawit (OPS) yang telah dinyahlemak. Partikel nano OPS telah dinyahlemak melalui kaedah
pengestrakan pelarut. Beberapa kaedah analisis termasuk mikroskop
elektron pancaran (TEM), pembelauan sinar-X (XRD),
penganalisis saiz partikel, mikroskop elektron imbasan (SEM), SEM sinar-X serakan tenaga (SEM-EDX) dan penganalisis
gravimetrik terma (TGA) telah digunakan untuk mencirikan
partikel nano OPS yang tidak dirawat dan yang telah dinyahlemak.
Didapati bahawa 75.3% daripada partikel OPS telah ditukarkan kepada
partikel nano semasa proses pengisaran bola. Partikel nano OPS yang
diperoleh menerusi pengimejan SEM mempunyai kawasan permukaan
yang lebih kecil dengan bersudut, tidak teratur dan berbentuk hancur. Partikel nano OPS yang dinyahlemak tidak menunjukkan
sebarang pengumpulan semasa pemerhatian TEM. Walau
bagaimanapun, partikel nano OPS yang tidak dirawat mempunyai
suhu penguraian yang lebih tinggi berbanding dengan partikel nano OPS yang
dinyahlemak. Berdasarkan keputusan pencirian partikel
nano OPS, adalah jelas bahawa partikel nano OPS yang
dinyahlemak mempunyai potensi untuk digunakan sebagai pengisi dalam komposit
bio.
Kata kunci: Bahan komposit; partikel nano; pengekstrakan minyak;
pengekstrakan pelarut; pengisi nano; tempurung kelapa sawit
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*Pengarang untuk surat-menyurat; email: akhalilhps@gmail.com
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