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"Pada penelitian ini berhasil disintesis natrium alginat tercangkok poli akrilat-co-akrilamida yang dikompositkan dengan montmorillonite MMT , dan dengan penambahan mikronutrien berupa asam borat dan boraks ke dalam superabsorben nanokomposit dengan metode in situ dan eksitu. Kapasitas swelling optimum superabsorben nanokomposit pupuk lepas lambat asam borat dan boraks dengan metode in situ berturut ndash; turut adalah 247,030 g/g dan 515,093 g/g, sedangkan dengan metode eksitu adalah 305,421 g/g dan 455,514 g/g. Kapasitas release optimum superabsorben nanokomposit pupuk lepas lambat asam borat dan boraks dengan metode in situ berturut ndash; turut adalah 68,59 dan 72,76 , sedangkan pada metode eksitu 61,66 dan 78,08. Digunakan FTIR, SEM, TEM, XRD dan UV-Vis untuk mengkaraterisasi. Di dapatkan kapasitas release optimum mikronutrien dari superabsorben nanokomposit pupuk lepas lambat in situ pada pengujian UV-Vis untuk asam borat sebesar 2,328 ppm, sedangkan boraks sebesar 1,587 ppm. Untuk parameter laju swelling didapatkan dengan parameter laju optimum untuk superabsorben nanokomposit terhadap air, larutan asam borat, dan larutan boraks berturut-turut adalah 256,0177; 227;9296; 173;7719. Untuk parameter laju swelling didapatkan dengan parameter laju optimum untuk superabsorben nanokomposit insitu asam borat dan boraks berturut-turut adalah 241,4187; 203,9398. Orde yang didapatkan pada superabsorben nanokomposit yaitu orde-pseudo 1.

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In this study succeeded in synthesized sodium alginate poly acrylate co acrylamide with montmorillonite MMT , and by addition of micronutrients in the form of boric acid and borax into nanocomposite superabsorbents by in situ and ex situ method. The optimum swelling capacity of superabsorbent nanocomposite of slow release of boric acid and borax by in situ method were 247.030 g g and 515,093 g g, respectively, with ex situ is 305,421 g g and 455,514 g g. The optimum release capacity of superabsorbent nanocomposite of slow release of boric acid and borax by in situ method was 68.59 and 72.76, respectively, while in the ex situ method 61.66 and 78.08. Used FTIR, SEM, TEM, XRD and UV Vis for electartizing. In obtaining the optimum release capacity of micronutrients from superabsorbent nanocomposite loose in situ fertilizers in UV Vis testing for boric acid was 2,328 ppm, while borax was 1,587 ppm. For swelling rate parameters with optimum rate parameters for superabsorbent nanocomposite to air, boric acid solution, and borax solution were 256,0177 227 9296 173 7719. For swelling rate parameters with optimum rate parameters for superabsorbent nanocomposites in situ boric acid and borax are 241,4187 203.9398. The order "

"Bahan bakar terbarukan seperti biodiesel merupakan salah satu sumber energi alternatif untuk mengatasi keterbatasan sumber daya energi. Senyawa oksida logam yang dimodifikasi telah banyak digunakan sebagai katalis pada sintesis biodiesel. Nanokomposit MgFe2O4-MgO telah berhasil disintesis pada penelitian ini. Telah dilakukan sintesis MgFe2O4 dan MgO dengan metode sol-gel dan hasil karakterisasi senyawa tersebut dengan FTIR, XRD, SEM dan TEM menunjukkan keberhasilan sintesis. Hasil XRD menunjukkan struktur berupa fasa kristalin. Hasil SEM dan TEM menunjukkan bentuk MgFe2O4 berupa sphere dengan ukuran rata-rata 39 nm. Variasi rasio mol MgFe2O4 terhadap MgO yaitu 1:1, 1:2 dan 1:3, diperoleh hasil terbaik yaitu 1:2. Aktivitas katalitik diuji melalui reaksi esterifikasi metil ester (biodiesel) dari asam oleat. Hasil konversi nanokomposit MgFe2O4-MgO menunjukkan nilai terbaik sebesar 96,089%. Hasil pengujian dengan GC-MS menunjukkan produk yang terbentuk yaitu metil oleat dengan rumus molekul C19H34O2.

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Renewable fuels such as biodiesel are one of the alternative energy sources to overcome the limitations of energy resources. Metal oxide compounds have been widely used as catalysts in biodiesel production. MgFe2O4-MgO nanocomposite was successfully synthesized in this study. The synthesis of MgFe2O4 has been prepared by sol-gel metode and characterization of sample using FTIR, XRD, SEM and TEM showed the success of synthesis.

XRD results show the structure of MgFe2O4 to be a crystalline phase. The results of SEM and TEM show that structure of MgFe2O4 form nanosphere with size about 39 nm. The variation of mole ratio of MgFe2O4 to MgO were 1: 1, 1: 2 and 1: 3, the best result was obtained 1: 2. Catalytic activity of MgFe2O4-MgO was tested by esterification of methyl oleate (biodiesel) from oleic acid show result 96,089%. The results of testing with GC-MS show that the product formed is methyl oleate with the molecular formula C19H34O2."

"ABSTRAKA natural-based nanocomposite film consisting of chitosan, montmorillonite (MMT) and cashew nut shell liquid (CNSL) was synthesized. The nanocomposite was prepared by mixing a suspension of clay particles (filler, MMT) with a solution containing chitosan as the macroscopic polymer matrix. In this study, it was proposed that non-ionic long-chain alkylmolecules with possible interact ions with the amine group of chitosan could be used as a plasticizer. As a natu-ral source for these compounds, an extract of CNSL was used. A series of chitosan/MMT com-posite samples containing two different clay contents and a sample with an additional CNSL were prepared. FTIR spectroscopy of the nanocomposite films indicated that, by addition of CNSL, amide groups of the chitosan are probably less attached and have more space for vibration. CNSL seems to provide intermolecular spaces between the chitosan molecules. Atomic force microscopy (AFM) analysis showed that the composite containedparticles measuring 100 nm or less, which confirmed that the nanocomposite had been successfully produced by this method. Addition of CNSL as plasticizer improved the tensile strength by 10% and the elastic modulus by almost 18%. Cell growth was observed on all the nanocomposite samples studied."

"Nanokomposit TiO2/CuO dengan variasi rasio Cu/Ti disusun menggunakan metode sol-gel. Sampel komposit dikarakterisasi dengan X-Ray Diffraction, Energy Dispersive X-Ray Spectroscopy, Field Emission Scaning, Brunauer-Emmett-Teller, UV-Visible Diffuse Reflectance Spectroscopy dan Electronic Spin Resonance Spectroscopy. Methylene blue digunakan sebagai model pewarna tekstil untuk mengevaluasi fotokatalitik, sonokatalitik dan fotosonokatalitik. Difraksi sinar-X dan dispersif energi analisis X-ray menegaskan bahwa hanya struktur monoklinik CuO dan struktur anatase TiO2 yang muncul di nanokomposit TiO2/CuO. Degradasi methylene blue menunjukkan bahwa penggabungan CuO di nanokomposit TiO2/CuO menunjukkan aktivitas fotokatalitik yang cukup tinggi, dan energi cahaya yang dapat dimanfaatkan lebih banyak dibandingkan TiO2 murni. Selain itu, degradasi methylene blue juga diselidiki menggunakan sistem sonokatalisis dan sistem fotosonokatalisis. Hasil penelitian menunjukkan bahwa semua data eksperimen mengikuti model pseudo-first order tapi laju konstanta fotosonokatalisis lebih tinggi dari proses fotokatalisis dan sonokatalisis individu masing-masing. Selain itu, kegiatan fotokatalitik, sonokatalitik dan fotosonokatalitik akan berkaitan dengan sifat struktural dan optik sampel. Mekanisme kegiatan katalitik akan dibahas.

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TiO2/CuO nanocomposite with different Cu/Ti ratios were prepared using sol-gel method. The obtained composite samples were characterized with X-Ray Diffraction, Energy Dispersive X-Ray Spectroscopy, Field Emission Scaning, Brunauer-Emmett-Teller, UV-Visible Diffuse Reflectance Spectroscopy and Electronic Spin Resonance Spectroscopy. Methylene blue was used as a model of textile dye to evaluate their photocatalytic, sonocatalytic and photosonocatalytic activities. X-ray diffraction and energy dispersive X-ray analysis confirmed that only monoclinic CuO and anatase TiO2 structures are present in TiO2/CuO nanocomposites. The degradation of methylene blue indicated that the incorporation of CuO in TiO2/CuO nanocomposite exhibited an appreciable higher photocatalytic activity, and more light energy could be utilized than pure TiO2. In addition, the degradation of methylene blue was also investigated using sonocatalysis and photosonocatalysis systems. The results showed that all experimental data followed the pseudo-first order model but the rate constant of the sonophotocatalysis is higher than the respective individual photocatalysis and sonocatalysis process. Furthermore, the photocatalytic, sonocatalytic and photosonocatalytic activities will be related to their structural and optical properties. The mechanism of catalytic activities will be discussed."

"The synthesis and characterization of nickel-graphite (Ni-C) nanocomposite materials by mechanical milling method have been performed. This composite was prepared by mixing high purity nickel and graphite. The mixture was milled for 25, 50, and 75 hours and then was compacted at pressure of 5000 psi. The samples consist of two phases, namely carbon and nickel phases. Carbon phase has hexagonal structure, space group: P 63 m c (186), lattice parameters of a = b = 2.352(1) Å and c = 6.669(7) Å, ? = ? = 90o and g = 120o, V = 31.9(7) Å3 and r = 5.585 gr.cm-3. Nickel phase has cubic structure, space group: F m -3 m (225), lattice parameters of a = b = c = 3.5254(7) Å, ? = ? = g = 90o, V = 43.81(2) Å3 and r = 8.898 gr.cm-3. The calculation results show that the crystallite size of the Ni-C75 sample was around 3.83 nm. The Ni-C75 sample is also suspected to have grown embryo of carbon nanotube (CNT) due to the presence of nickel. The hysteresis loop of the sample consists of intrinsic saturation Ms, remanence Mr, and coercivity Hc are 1.40 emu/gr, 0.28 emu/gr, and 128 Oe, respectively. The value of MR is about 28% at 7.5 kOe magnetic field. The sample shows magnetoresistance behavior and the phenomenon of sensor characteristics. We concluded that this study has successfully made Ni-C nanocomposite and it is expected that the nano composite Ni-C is able to be used for sensor material application."

"Modifications of the TiO2 P25 photocatalyst with metals: Platinum (Pt), Copper (Cu) and non-metal: Nitrogen (N) doping to produce Hydrogen (H2) from a glycerol-water mixture have been investigated. The metals (Pt and Cu) were loaded into Titanium Dioxide (TiO2 ) surface by employing an impregnation and Photo-Assisted Deposition (PAD) method, respectively. As prepared the metal doped TiO2 photocatalyst was then dispersed into an ammonia solution to obtain N-doped photocatalysts. The modified photocatalysts were characterized by X-Ray Diffraction (XRD), Scanning Electron Microscopy (SEM), and Ultraviolet-Visible Diffuse Reflectance Spectroscopy (UV-Vis DRS). XRD patterns indicated that the modified TiO2 photocatalysts have a nano-size crystallite range of 16-23 nm, while the DRS analysis showed that the doping of both metal and non-metal into TiO2 photocatalysts could effectively shift photon absorption to the visible light region. The optimum Cu loading of Cu-N-TiO2 was found to be 5%, resulting in a 10 times higher H2 production improvement level when compared to unloaded TiO2, even though this is still considered to be inferior compared to that of a 1% Pt loading, which results in a 34 times higher level than an unmodified TiO2photocatalyst. The effect of glycerol concentrations on hydrogen production has also been studied. This method offers a promising technology to find renewable and clean energy by using cheap materials and a simple technology."

"ABSTRAKShape Memory Polyurethane (SMPU) telah disintesis dari penambahan polyethylene glycol (PEG-6000) sebagai segmen lunak dan 4,4'-Methylenebis (Cyclohexyl isocyanate) (HMDI) sebagai segmen keras serta 1,1,1-Trimethylol propane (TMP) sebagai chain extender. SMPU lalu ditambahkan nanopartikel Fe3O4 berukuran 20-50 nm untuk meningkatkan sifat kemagnetan. Untuk mengkonfimasi bentuk ikatan antarmuka komposit SMPU digunakan FTIR (Fourier Transform Infrared Spectroscopy). FE-SEM digunakan untuk mengetahui interface dari filler dan matriks SMPU. Konfirmasi nilai kemagnetan menggunakan VSM (vibrating sampel magnetometer) dan pengujian tarik menggunakan microtensile menunjukkan bahwa penambahan Fe3O4 dengan persentase 11 wt% menghasilkan nilai kemagnetan dan sifat mekanik tertinggi.

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ABSTRACTShape Memory Polyurethane (SMPU) has been synthesized by reacting polyethylene glycol (PEG-6000) as softsegment, 4,4'-Methylenebis (Cyclohexyl isocyanate) (HMDI) as hardsegment and 1,1,1-Trimethylol propane (TMP) as chain extender. SMPU was added by Fe3O4 as filler to provide magnetical property. Magnetite which had confirmed by Scanning Elctron Magnetic (SEM) have size 20-50 nm. Functional group was investigated by FTIR (Fourier Transform Infrared Spectroscopy). The magnetic behavior of the nanocomposites was observed by vibrating sample margnetometer (VSM). FE-SEM is used to acknowledge interface between filler and Shape Memory Polyurethane (SMPU) matrix. Mechanical properties tested by microtensile testing showed adding 11% Fe3O4 obtaining magnetic and nanocomposites SMPU resulted in improved materials with higher magnetical and mechanical properties."

"[Komposit bermatriks aluminium dengan penguat partikel Al2O3 berukuran nano umum digunakan untuk aplikasi dengan performa yang tinggi karena aluminium memiliki sifat ringan dan Al2O3 memiliki performa yang baik pada suhu tinggi. Pada penelitian ini, penambahan Al2O3 dengan fraksi volum 0,2%, 0,5%, 0,7%, 1,0%, and 1,2% dilakukan untuk menentukan titik optimum dari kelima komposisi. Magnesium sebanyak 10 wt.% ditambahkan sebagai wetting agent. Hasil penelitian menunjukkan kekuatan optimum dicapai dengan penambahan fraksi volum nano-Al2O3 sebanyak 0,2% dengan 200,84 MPa dan keuletan yang baik, didukung dengan rendahnya porositas, rendahnya aglomerasi, dan pembentukan dimple pada permukaan patah.

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Aluminium Matrix Composites (AMCs) reinforced with nano-sized Al2O3 particles are widely used for high performance application because aluminium has light weight and alumina has good performance at high temperature. In this study, the percentage of nano-sized Al2O3 with volume fraction 0.2%, 0.5%, 0.7%, 1.0%, and 1.2% are performed to determine the optimum point of the fifth variation. Magnesium with 10 wt.% are added as a wetting agent. The result showed the optimum strength was reached by 0.2 %Vf nano-Al2O3 reinforced composite with 200.84 MPa and enough ductility, supported by evidence low porosity, low agglomeration, and dimples formation on SEM image.

, Aluminium Matrix Composites (AMCs) reinforced with nano-sized Al2O3 particles are widely used for high performance application because aluminium has light weight and alumina has good performance at high temperature. In this study, the percentage of nano-sized Al2O3 with volume fraction 0.2%, 0.5%, 0.7%, 1.0%, and 1.2% are performed to determine the optimum point of the fifth variation. Magnesium with 10 wt.% are added as a wetting agent. The result showed the optimum strength was reached by 0.2 %Vf nano-Al2O3 reinforced composite with 200.84 MPa and enough ductility, supported by evidence low porosity, low agglomeration, and dimples formation on SEM image.

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"Nanokomposit berbasis polimer yang didukung oleh oksida logam, menarik untuk dikembangkan sebagai katalis untuk produksi biodiesel. Dalam penelitian ini, nanokomposit selulosa/α-Fe2O3/ZrO2 telah berhasil disintesis dengan memanfaatkan limbah jerami padi sebagai sumber isolasi nanoselulosa, Zirkonium Oksida (ZrO2) disintesis melalui kopresipitasi, Hematite (α-Fe2O3) disintesis melalui kopresipitasi yang didukung oleh karakterisasi FTIR, XRD, SEM dan TEM. Hasil pengujian dengan SEM dan TEM menunjukkan morfologi isolasi nanoselulosa berupa fibril panjang dengan ukuran panjang sekitar 171 nm dan diameter 43 nm. Hasil pengujian XRD menunjukkan struktur Hematite (α-Fe2O3) dan Zirkonium Oksida (ZrO2) berupa fasa kristalin. Aktivitas katalitik diuji melalui reaksi esterifikasi metil laurat (biodiesel) dari asam laurat. Kondisi optimum reaksi esterifikasi diperoleh dengan jumlah katalis 2% terhadap asam laurat dan waktu reaksi 3 jam. Hasil persen konversi biodiesel menggunakan nanokomposit selulosa/α-Fe2O3/ZrO2 menunjukkan nilai terbaik sebesar 62,85%. Energi aktivasi konversi asam laurat menjadi produk pada penambahan nanokomposit selulosa/α-Fe2O3/ZrO2 sekitar 31,24 kJ.mol-1. Parameter kinetika dari reaksi dievaluasi mengikuti pseudo-orde pertama. Komposisi FAME ditentukan dengan GC-MS.

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Nanocomposites of metal oxide supported by biopolymer are interesting to be developed as catalyst for biodiesel production. In this study, cellulose/α-Fe2O3/ZrO2 nanocomposite was successfully synthesized by utilizing rice straw waste as a source of nanocellulose biopolymer, Zirconium Oxide (ZrO2) was synthesized via coprecipitation, Hematite (α-Fe2O3) was synthesized via coprecipitation in which their characterizations were conducted by FTIR, XRD, SEM, and TEM. The composition of fatty acid methyl ester was determined using gas chromatography-mass spectroscopy. The results of testing with SEM and TEM show the morphology of nanocellulose isolation in the form of long fibrils with a length of about 171 nm and a diameter of 43 nm.

The XRD test results showed Hematite (α-Fe2O3) and Zirconium Oxide (ZrO2) structures in the form of crystalline phase. Catalytic activity was tested by esterification of methyl laurate (biodiesel) from lauric acid. The optimum conditions for the esterification reaction were obtained by the amount of catalyst 2% against lauric acid and reaction time of 3 hours. The results of percent biodiesel conversion using cellulose/α-Fe2O3/ZrO2 nanocomposite showed the best value of 62.85%. The activation energy of lauric acid conversion into a product at the addition of cellulose/α-Fe2O3/ZrO2 nanocomposite is around 31.24 kJ.mol-1. The kinetic parameter of the reaction was also evaluated following the pseudo-first order equation."

"Pada penelitian ini telah dilakukan sintesis nanokomposit nanochitosan/ZnO-CdO dengan nanochitosan sebagai support katalis dengan semikonduktor ZnO yang digabungkan dengan CdO yang dimanfaatkan untuk degradasi limbah zat warna methylene blue. Pada penelitian ini sintesis nanochitosan telah berhasil dilakukan dengan ukuran partikel sebesar 17,72 nm. Nanopartikel ZnO telah berhasil disintesis dengan ukuran partikel 30,65 nm dan energi band gap 3,17 eV. Nanopartikel CdO telah berhasil disintesis dengan ukuran partikel 23,14 nm dan energi band gap 2,13 eV. Komposit ZnO-CdO berhasil disintesis dengan energi band gap 2,42 eV, hal itu menunjukkan bahwa CdO dapat menurunkan energi band gap dari ZnO. Komposit ZnO-CdO yang disintesis memiliki luas permukaan 18,60 m2/g dengan analisis SEM berbentuk butiran tidak seragam. Nanokomposit nanochitosan/ZnO-CdO telah berhasil disintesis dengan ukuran kristal 20,82 nm, luas permukaan 40,34 m2/g, dan menggunakan TEM diperoleh ukuran rata-rata pertikel 23,97 nm. Nanokomposit nanochitosan/ZnO-CdO yang telah berhasil disintesis digunakan untuk fotokatalisis untuk mendegradasi zat warna methylene blue dan diperoleh persen degradasi 97,10%. Studi kinetika mengikuti kinetika orde satu dengan persamaan laju reaksi yang berarti laju reaksi bergantung pada konsentrasi methylene blue. Isoterm adsorpsi sesuai dengan isoterm Langmuir menunjukkan proses kemosorpsi yang mana proses degradasi zat warna methylene blue menggunakan nanokomposit nanochitosan/ZnO-CdO ini termasuk fotokatalisis. Berdasarkan hasil penelitian ini nanokomposit menggunakan support biopolimer seperti nanochitosan dengan ZnO-CdO memiliki potensi katalis yang baik untuk berbagai aplikasi yang ramah lingkungan.

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In this study, a nanochitosan based nanochitosan/ZnO-CdO nanocomposite was synthesized as a catalyst support with ZnO semiconductor combined with CdO which used for the degradation of methylene blue dye. In this study, nanochitosan was successfully synthesized with a particle of 17,72 nm. ZnO nanoparticle has been successfully synthesized with a particle size of 30,65 nm and band gap energy of 3,17 eV. CdO nanoparticle has been successfully synthesized with a particle size of 23,14 nm and band gap energy of 2,13 eV. ZnO-CdO composite was successfully synthesized with band gap energy of 2,42, it shows that CdO can reduce the band gap energy of ZnO. The ZnO-CdO composite obtaine a surface area of 18,60 m2/g by SEM analysis in the form of non-uniform grains. Nanochitosan/ZnO-CdO nanocomposite has been successfully synthesized with a crystal size of 20,82 nm, a surface area 40,34 m2/g, and using TEM an average particle size of 23,97 nm was obtained. The successfully synthesized nanochitosan/ZnO-CdO nanocomposite was used as a photocatalyst to degrade methylene blue dye, the optimum degradation percentage was 97,10%. In the study of kinetics following one order kinetic with the equation for the reaction rate is which means the reaction rate depends on the concentration of methylene blue dye. The study of adsorption isotherm according to Langmuir isotherm shows a chemosorption process in which the degradation process of methylene blue dye using nanochitosan/ZnO-CdO nanocomposite is photocatalytic. Based on the results of this study, nanocomposite using biopolymer support which nanochitosan have good catalyst potential for various environmentally friendly applications. "