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"ABSTRAKSenyawa metal alloy (LaNi5) biasa digunakan untuk anode baterai Nickel-Metal Hydride (NiMH) karena mampu mengabsorpsi hidrogen dan dapatberoperasi pada kondisi tekanan dan temperatur ruang. Ketika oksida logam tanahjarang ditambahkan ke dalam anode sel baterai NiMH, tidak hanya chargeefficiency dan capacity-retention yang akan meningkat, tetapi juga menjadi rapidcharge dan high power cycling. Penelitian dilakukan untuk melihat karakteristikbahan anode LaNi5 setelah penambahan CeO2 dan proses anil. Metode yangdigunakan adalah mechanical alloying dengan mencampur serbuk LaNi5 denganserbuk CeO2 sebanyak 1%, 2%, dan 3% berat di dalam ball mill selama 120 menitpada putaran 240 rpm. Setelah itu, dilakukan proses anil pada temperatur 300°C,600°C, dan 900°C selama 6 jam di lingkungan gas argon. Kemudian, serbukdikarakterisasi dengan menggunakan XRD, SEM-EDX, dan BET. Pengujianelektrokimia dilakukan dengan menggunakan Electrochemical ImpedanceSpectroscopy (EIS) pada frekuensi 5 mHz ? 100 kHz. Penambahan konsentrasiCeO2 diatas 2%, akan memperkecil volume cell dan mengecilkan diameter pori.Konduktivitas tertinggi yang dicapai pada penelitian ini adalah sebesar 1.5332S/cm dengan diameter pori 0.0082 cc/g. Walaupun penambahan konsentrasi CeO2ke dalam material anode meningkatkan tahanan material, tetapi penambahan 1%CeO2 dapat meningkatkan ketahanan korosi material anode dengan Ecorr sebesar -0.6432 V. Peningkatan temperatur anil menyebabkan perubahan difraksi fasamenjadi fasa NiO dan La2O3 yang menyebabkan konduktivitas menurun dan nilaitahanan semakin besar.

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ABSTRACTA Lanthanum Nickel compound (LaNi5) is widely used for an anode ofNickel-Metal Hydride (NiMH) battery due to excellence on hydrogen absorptionand good capability to be operated at room temperature and pressure condition.Addition of rare earth oxide to the NiMH has increase charge-retention efficiencyand capacity also has both rapid charge and high power cycling. The experimenthas been conducted to observe the characteristic of the anode LaNi5 materialsafter addition of CeO2 and annealing. As method of this experiment, mechanicalalloying was done by mixed LaNi5 and CeO2 powder which had 1%, 2% and 3%weight mass in ball mill for 120 minutes at 240 rpm. After that, the annealing wascarried out at varied temperature, 300°C, 600°C and 900°C for 6 hours in argongas exposure. Then the powders were characterized with XRD, SEM-EDX, andBET. Electrochemical Impedance Spectroscopy (EIS) was used forelectrochemical testing on the frequency between 5 mHz - 100 kHz. The results ofthis experiment show that increasing CeO2 more than 2% concentration lead todecrease the volume of cells and the pore diameter. Furthermore, this is affect thevalue of ionic conductivity with the highest conductivity is 1.5332 S / cm and0.0082 cc / g in diameter pore. Although the addition of CeO2 concentration intothe anode material increases the resistance, the addition of 1% CeO2 can improvethe corrosion resistance of the anode material with Ecorr of -0.6432 V. Inconclusions, annealing temperature increasing will changes diffraction phase withthe dominant phase NiO and La2O3, thus the conductivity was decreasing and theresistance was increasing."

"Fuel cell urea membutuhkan katalis berbasis logam Ni. Tetapi logam Ni memiliki sifat over potensial yang tinggi sehingga menurunkan efisensi fuel cell. Doping dengan MnO2 dapat menurunkan over potensial Ni. Oleh karena itu pada penelitian ini NiMn2O4 dideposisi dengan metode hidrotermal pada permukaan busa nikel untuk digunakan sebagai katalis pada anoda fuel cell urea. Pendeposisian dilakukan pada struktur busa nikel yang berpori menggunakan larutan Mn(NO3)2.6H2O dan Ni(NO3)2.6H2O sebagai prekusor nikel dan mangan dengan kehadiran urea. Reaksi dilakukan autoclave dan dipanaskan di dalam furnace dengan suhu 180° C selama 24 jam. Dilanjtkan dengan annealing pada 400° C selama 2 jam. Hasil penelitian menunjukkan bahwa busa nikel telah berhasil dimodifikasi dengan NiMn2O4. NiMn2O4/busa nikel menunjukkan densitas arus yang baik untuk fuel cell urea berdasarkan hasil cyclic voltammetry. Variasi konsentrasi prekusor nikel dan mangan pada rasio 1:1 menunjukkan hasil terbaik dengan densitas arus sebesar 206.453 mA cm-2 didalam larutan 2 M KOH dan 0.33 M Urea. Aplikasi pada Direct Urea Fuel Cell menunjukkan densitas daya yang dihasilkan adalah 0.304 mW cm-2 dengan mengunakan larutan 2 M KOH dan 0.33 M Urea dalam anoda dan larutan 2 M H2O2 dan 2 M H2SO4 pada katoda.

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ABSTRACTUrea fuel cells require a Ni metal-based catalyst. However, Ni metal has high over potential properties, thus reducing fuel cell efficiency. Doping with MnO2 can reduce the over potential of Ni. Therefore, in this study NiMn2O4 was deposited by hydrothermal method on the surface of nickel foam to be used as a catalyst in the urea fuel cell anode. The deposition was carried out on the porous nickel foam structure using a solution of Mn(NO3)2.6H2O and Ni(NO3)2.6H2O as a precursor to nickel and manganese in the presence of urea. The reaction is autoclaved and heated in a furnace at 180 ° C for 24 hours. Continued with annealing at 400 ° C for 2 hours. The results showed that nickel foam was successfully modified with NiMn2O4. NiMn2O4 / nickel foam shows good current density for urea fuel cells based on cyclic voltammetry results. The variation in the concentration of nickel and manganese precursors at a 1: 1 ratio showed the best results with a current density of 206,453 mA cm-2 in a 2 M KOH solution and 0.33 M Urea. Application to the Direct Urea Fuel Cell shows that the resulting power density is 0.304 mW cm-2 using a 2 M KOH solution and 0.33 M Urea in the anode and a 2 M H2O2 and 2 M H2SO4 solution at the cathode."

"In this book, contributions from leadingexperts emphasize basic physical properties, synthesis and processing, and thelatest applications in such areas as energy, catalysis and data storage. Functional metal oxide nanostructuresis an essential reference with aninterest in metal oxides, and particularly in recent progress in defectphysics, strain effects, solution-based synthesis, ionic conduction, and theirapplications."

"Pada penelitian ini preparasi komposit busa nikel termodifikasi mangan oksida dan graphene dan uji performanya sebagai elektroda untuk superkapasitor telah berhasil dilakukan. Karakterisasi menggunakan SEM-EDX dan spektroskopi Raman menunjukkan morfologi berupa bercak putih dari keberadaan mangan oksida pada kerangka busa nikel. Sedangkan karakterisasi dengan Spektroskopi Raman menunjukkan adanya puncak peak yang mengindikasikan D band dan G band dengan rasio ID/IG yang dapat menentukan keberadaan material elektroaktif graphene. Uji elektrokimia menggunakan teknik Cyclic Voltammetry (CV) menunjukkan nilai kapasitansi spesifik tertinggi pada Busa nikel/MnO2/Graphene dalam electrolit hydrogel PVA-Na2SO4 yaitu sebesar 806,16 F/g pada scanrate optimum 25 mV.s-1. Uji elektrokimia menggunakan teknik Electrochemical Impedance Spectroscopy (EIS) menunjukkan performa terbaik adalah pada Busa nikel/MnO2/Graphene dalam electrolit Na2SO4 sebesar 348,42 F/g .Uji elektrokimia menggunakan teknik Galvanostatic Charge- discharge (GCD) menunjukkan performa terbaik adalah pada Busa nikel/MnO2/Graphene dalam electrolit PVA-Na2SO4 pada arus yang diberikan sebesar 2 mA, dengan nilai kapasitansi spesifik mencapai 1680,67 F/g, densitas energi sebesar 43,60 Wh/kg dan densitas daya sebesar 838,8 W/kg.

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In this study, the preparation of a modified nickel foam composite of manganese oxide and graphene and its performance test as an electrode for a supercapacitor have been successfully carried out. Characterization using SEM- EDX and Raman spectroscopy showed morphology in the form of white spots from the presence of manganese oxide in the nickel foam framework. Meanwhile, the characterization using Raman Spectroscopy showed the presence of peaks indicating D band and G band with ID/IG ratio which can determine the presence of graphene electroactive material. Electrochemical test using Cyclic Voltammetry (CV) technique showed the highest specific capacitance value in nickel/MnO2/Graphene foam in hidrogel electrolyte PVA-Na2SO4, which was 806,16 F/g at an optimum scanrate of 25 mV.s-1. The electrochemical test using the Electrochemical Impedance Spectroscopy (EIS) technique showed the best performance was on nickel/MnO2/Graphene foam at 348,42 F/g. The electrochemical test using the Galvanostatic Charge-discharge (GCD) technique showed the best performance was on nickel/MnO2/Graphene in hidrogel electrolyte PVA-Na2SO4 at a given current of 2 mA, with a specific capacitance value of 1680,67 F/g, an energy density of 43,60 Wh/kg and a power density of 838,8 W/kg."

"Sistem pori hierarki pada zeolit yang dikembangkan untuk mengatasi keterbatasan zeolit konvensional dapat diperoleh dengan penambahan pori dan dapat menghasilkan dua bentuk konfigurasi mesopori, yaitu mesopori intra dan interkristalin. Mesopori intrakristalin merupakan pori berukuran meso yang terletak pada kristal zeolit, sedangkan mesopori interkristalin merupakan pori berukuran meso yang terbentuk sebagai celah di antara nanozeolit yang masing-masing disintesis menggunakan metode templating dan mesoporogen-free. Penelitian ini dilakukan untuk menganalisa pengaruh konfigurasi mesopori terhadap sifat fisika-kimia dari ZSM-5 hierarki dan pengaruhnya terhadap kobalt oksida yang dimodifikasikan secara impregnasi. Analisa sifat fisika-kimia ZSM-5 termodifikasi oksida kobalt dilakukan berdasarkan karakterisasi XRD, FTIR, XRF, N2 physisorption, SEM, TEM, H2-TPR, dan XPS. Kemudian reaksi oksidasi parsial metana diujikan sebagai reaksi model untuk menganalisa pengaruh konfigurasi mesopori terhadap aktivitas katalisis ZSM-5 hierarki termodifikasi oksida kobalt. Uji katalisis oksida metana dengan variasi waktu menghasilkan produk teroksidasi berupa metanol, formaldehida, asam format, dan karbon dioksida. Hasil uji katalisis menunjukkan bahwa konfigurasi mesopori interkristalin cenderung mengoksidasi reaksi lebih kuat yang dikonfirmasi bahwa pada waktu tersingkat, yaitu 30 menit, dihasilkan formaldehida sebagai produk utama yang merupakan hasil oksidasi lanjutan dari senyawa metanol.

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Zeolite hierarchical porous system that was developed to overcome the limitations of conventional zeolite could be achieved though the introduction of secondary porous system and could lead to the creation of two types of mesoporous configuration: intra- and inter-crystalline mesopore. Intracrystalline mesoporous presented within zeolite crystals white inter-crystalline mesoporous presented as voids between zeolite crystals where both were synthesized through templating and mesoporogen-free method, respectively. In this study, the influence of mesoporous configuration to the physicochemical properties of hierarchical ZSM-5 are analysed, including the influence on the creation of cobalt oxide modified via impregnation method. Analysis of physicochemical properties were determined by characterization using XRD, FTIR, XRF, N2 physisorption, SEM, TEM, H2-TPR, and XPS. Analysis on the catalytic activity were carried out using methane partial oxidation reaction as model reaction. Methane oxidation reaction with variation of reaction time showed various type of oxygenated products, including of methanol, formaldehyde, formic acid, and small trace of carbon dioxide. Catalytic results suggested that catalysts with inter-crystalline mesoporous configuration oxidize reaction stronger compared to intracrystalline type. These results confirmed by the formation of formaldehyde as the oxygenated form of methanol as major product in the brief reaction time of 30 mins."

"ABSTRAKKaca konduktor memiliki fungsi strategis di berbagai aplikasi elektronik. Jenisyang menjanjikan adalah Fluorine-doped Tin Oxide (FTO). Dalam penelitian inidilakukan studi pengaruh waktu deposisi (5, 10, 20, 30, dan 40 menit) lapisan tipisFTO dengan metode spray pyrolysis menggunakan alat ultrasonic nebulizer yangtelah dimodifikasi terhadap nilai karakteristik lapisannya ditinjau dari sifat optis,kristalinitas, resistivitas, dan mikrostruktur. Variasi juga dilakukan denganmembandingkan prekursor Sn murni dan larutan yang telah didoping dengan Fsebanyak 2%wt untuk melihat pengaruh penambahan doping F pada larutanprekursor. Pengujian karakteristik lapisan dilakukan menggunakan XRD, SEM,UV-Vis spectroscopy, dan digital multimeter. Berdasarkan karakterisasi yangdilakukan diperoleh nilai terbaik untuk FTO yang dihasilkan adalah pada waktudeposisi 20 menit dengan nilai transmitansi 74%, energi band gap (Eg) 3,85 eV,dan sheet resistance (Rs) 7,99 Ω/sq.

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ABSTRACTConductive glass has strategic functions in various electronic applications. Oneof the lead is Fluorine-doped Tin Oxide (FTO). In this research, the effects ofdeposition time (5,10,20,30, and 40 minutes) for fabrication of FTO thin film uponspray pyrolysis process using modified ultrasonic nebulizer on its characteristicin terms of optical, crystalinity, resistivity and microstructure properties has beenstudied. Variation was also performed by comparing the pure Sn precursor andthe solution that has been doped with F 2%wt to see the doping effect toproperties of thin film. The thin film characterization were carried out using XRD,SEM, UV-Vis spectroscopy, and digital mutlimeter. Based on the results obtainedfor the best FTO was generated at the time of deposition is 20 minutes. Providing74% transmittance, band gap energy (Eg) 3.85 eV and sheet resistance (Rs) 7.99Ω/sq."

"Solid sorbents based on graphite electrode waste and cerium oxide (ceria, CeO2) have been studied with regard to CO2 capture. The acid-base properties of cerium oxide produce a sorbent for the capture of CO2. The aim of the study is to evaluate the performance of CO2 capture using graphite/CeO2 composites at different weights of Ce(NO3)3.6H2O (0.5, 1 and 2 g), namely G0.5, G1 and G2, respectively. Volumetric adsorption studies of CO2 on graphite/CeO2 composites and ceria were conducted at various pressures (P) of 3, 5, 8, 15 and 20 bar, and temperatures (T) of 303, 308, 318 K. Graphite waste before modification (GBM), activated graphite waste (GA), and CeO2 for capturing CO2 were also investigated. By varying the two parameters (P and T), we found that the maximum adsorption capacities of CO2 at 303 K and 20 bar were 0.0713, 0.0316, 0.1574, 0.0987, 0.1137, and 0.0964 kg/kg respectively, for GBM, GA, G0.5, G1, G2 and CeO2. The highest adsorption capacity of CO2 was found in the G0.5 composite. The adsorption performance of CO2 using ceria was almost similar to the G1 composite. We found that CO2 adsorption capacity decreases with an increasing temperature from 303 to 318 K. It was concluded that ceria and composite graphite waste/CeO2 are stable and selective CO2 sorbents. The work allows us to synthesize a new sorbent which can be effectively applied for CO2 capture. The adsorption capacity of CO2 depends significantly on the active site and chemical modifier of the sorbents."

"Pada studi ini, tiga persentase massa dari perak ditambahkan ke nanokomposit oksidanikel dan oksida cerium dengan tiga rasio molar berbeda dari kedua oksida.Nanokomposit telah disintesis menggunakan metode ultrasonic-assisted. Lima teknikkarakterisasi digunakan untuk mengevaluasi bahan, X-ray diffraction (XRD), X-rayfluorescence (XRF), UV-Vis diffuse reflectance, Raman Spectroscopy, danAdsorpsi/Desorpsi Nitrogen. Dua sumber radiasi, cahaya tampak UV digunakan untukmendegradasi metilen biru sebagai objek polutan untuk aktivitas fotokatalitik. Katalisnanokomposit dengan persentase massa Ag sebanyak 20 wt.% menunjukkan aktivitasfotokatalitik tertinggi. Dalam proses degradasi metilen biru dengan katalis nanokompositelektron scavenger merupakan spesies aktif utama pada proses degradasi

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In this study, three different weight percentages of silver were added to the nickel oxide

and cerium oxide nanocomposites with three different molar ratios of the two oxides.

These nanocomposites were synthesized using ultrasonic-assisted techniques. Five

characterization techniques were carried out to evaluate the materials, X-ray diffraction

(XRD), X-ray fluorescence (XRF), UV-Vis diffuse reflectance, Raman Spectroscopy,

and Nitrogen Adsorption/Desorption. Two radiation sources, visible and ultraviolet, were

used to degrade methylene blue as a pollutant object for photocatalytic activities. The

nanocomposite catalyst with twenty weight percentages of silver showed the highest

photocatalytic activity. In the degradation process of methylene blue with these

nanocomposite catalyst that electrons becomes the main active species in the process."