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Abstrak :
[Komposit Li4Ti5O12 dan Sn untuk material anoda baterai lithium-ion dipreparasi dengan 2 rute, yaitu sintesis Li4Ti5O12 (LTO) dengan metode hidrotermal dan mixing LTO dan Sn menggunakan ball mill. Tujuan dari penelitian ini adalah untuk memperoleh suhu kalsinasi yang optimum pembentukan fasa spinel LTO serta penambahan berat serbuk Sn yang tepat untuk memperoleh peningkatan performa LTO. Sampel dikarakterisasi menggunakan DT/TGA, XRD, SEM EDX, dan EIS. Sedang properti elektrokimia dianalisis menggunakan tes charge/discharge battery analyzer. Hasil menunjukkan telah terbentuk fasa spinel LTO dan butir tumbuh 17, 20, dan 40 nm masing-masing untuk suhu kalsinasi 500, 600, dan 700oC. Foto SEM memperlihatkan butir-butir berbusa dan mengalami aglomerasi yang merupakan efek dari proses sintesis hidrotermal. Dari penelitian ini diperoleh sampel komposit LTO 500oC dan Sn 10% dengan nilai konduktivitas tertinggi yaitu 9,06 x 10-7 S/cm. Uji cyclic voltammetry menunjukkan pasangan anodik-katodik tegangan reduksi-oksidasi LTO 1,5 dan 1,7 V, serta 1,71 dan 2,11 V untuk TiO2. Sedangkan tegangan litiasi Sn terdeteksi0,61 V. Untuk uji charge/discharge komposit LTO 500oC dan Sn 10% memperlihatkan penambahan Sn akan memberi keuntungan saat tegangan rendah (0,6 V) yaitu komposit masih memiliki kapasitas. Kapasitas spesifik untuk komposit LTO 500oC dan Sn 10% mencapai 110 mAh/g dengan C/3.;Li4Ti5O12 and Sn composites as anode material for lithium-ion battery have been prepared with two routes, ie. synthesis of Li4Ti5O12 (namely LTO) with hydrothermal method and mixing LTO and Sn using mechanical ball milling method. The purposes of this study are to obtain the optimum calcination temperatures LTO spinel phase formation and the precise addition of Sn powder is to obtain the improved performance of LTO. Samples have been characterized by DT/TGA, XRD, SEM EDX, and ElS. Meanwhile, electrochemical properties were analyzed using a charge-discharge test battery analyzer. Results showed that LTO spinel phase has been formed and the grains growth 17, 20, and 40 nm respectively for calcination temperature 500, 600, and 700°C. SEM photograph showing a grain foaming and run into agglomeration which is the effect of hydrothermal synthesis process. From this study, LTO 500oC and 10%Sn composite has the highest conductivity value ie 9.06 x 10-7 S/cm. Test cyclic voltammetry showed a couple of anodic-cathodic reduction-oxidation voltage LTO 1.48 and 1.74 V, and 1.65 and 2.11 V for TiO2. Lithiation voltage for Sn at 0.61 V. For test charge/discharge LTO 500oC and 10%Sn composite showed the addition of Sn will benefit current low voltage (0.6 V) is a composite still has capacity. Specific capacity for LTO 500oC and 10%Sn composite up to 110 mAh/g with C/3.;Li4Ti5O12 and Sn composites as anode material for lithium-ion battery have been prepared with two routes, ie. synthesis of Li4Ti5O12 (namely LTO) with hydrothermal method and mixing LTO and Sn using mechanical ball milling method. The purposes of this study are to obtain the optimum calcination temperatures LTO spinel phase formation and the precise addition of Sn powder is to obtain the improved performance of LTO. Samples have been characterized by DT/TGA, XRD, SEM EDX, and ElS. Meanwhile, electrochemical properties were analyzed using a charge-discharge test battery analyzer. Results showed that LTO spinel phase has been formed and the grains growth 17, 20, and 40 nm respectively for calcination temperature 500, 600, and 700°C. SEM photograph showing a grain foaming and run into agglomeration which is the effect of hydrothermal synthesis process. From this study, LTO 500oC and 10%Sn composite has the highest conductivity value ie 9.06 x 10-7 S/cm. Test cyclic voltammetry showed a couple of anodic-cathodic reduction-oxidation voltage LTO 1.48 and 1.74 V, and 1.65 and 2.11 V for TiO2. Lithiation voltage for Sn at 0.61 V. For test charge/discharge LTO 500oC and 10%Sn composite showed the addition of Sn will benefit current low voltage (0.6 V) is a composite still has capacity. Specific capacity for LTO 500oC and 10%Sn composite up to 110 mAh/g with C/3., Li4Ti5O12 and Sn composites as anode material for lithium-ion battery have been prepared with two routes, ie. synthesis of Li4Ti5O12 (namely LTO) with hydrothermal method and mixing LTO and Sn using mechanical ball milling method. The purposes of this study are to obtain the optimum calcination temperatures LTO spinel phase formation and the precise addition of Sn powder is to obtain the improved performance of LTO. Samples have been characterized by DT/TGA, XRD, SEM EDX, and ElS. Meanwhile, electrochemical properties were analyzed using a charge-discharge test battery analyzer. Results showed that LTO spinel phase has been formed and the grains growth 17, 20, and 40 nm respectively for calcination temperature 500, 600, and 700°C. SEM photograph showing a grain foaming and run into agglomeration which is the effect of hydrothermal synthesis process. From this study, LTO 500oC and 10%Sn composite has the highest conductivity value ie 9.06 x 10-7 S/cm. Test cyclic voltammetry showed a couple of anodic-cathodic reduction-oxidation voltage LTO 1.48 and 1.74 V, and 1.65 and 2.11 V for TiO2. Lithiation voltage for Sn at 0.61 V. For test charge/discharge LTO 500oC and 10%Sn composite showed the addition of Sn will benefit current low voltage (0.6 V) is a composite still has capacity. Specific capacity for LTO 500oC and 10%Sn composite up to 110 mAh/g with C/3.]

Abstrak :
Litium Titanat, Li4Ti5O12 (LTO) adalah kandidat yang menjanjikan sebagai bahan anoda baterai lithium ion. LTO dalam bentuk struktur nanorod akan lebih menjanjikan lagi dengan sifatnya yang lebih baik disbanding struktur biasa. Dalam penelitian ini, LTO nanorod akan disintesis dengan menggunakan bubuk TiO2 melalui cara hidrotermal dengan bantuan litium hidroksida (LiOH). Setelah itu, Grafit dan Nano-Timah akan ditambahkan Bersama LTO Nanorod. Tiga variasi penambahan konten Nano-Timah dalam % berat, yaitu, 5, 10 dan 15%, diberi label sampel LTO/C-5%Nano Sn, LTO/C-10%Nano Sn and LTO/C-15%Nano Sn. Karakterisasi dilakukan menggunakan XRD dan SEM untuk mengamati efek penambahan Nano-Timah pada struktur dan morfologi sampel yang dihasilkan. Hasil menunjukkan bahwa penambahan Nano-Ttimah 10% (LTO/C-10%Nano Sn) memiliki kapasitas spesifik tertinggi dengan 87.07 mAh g-1. Hasil dari tes Electrochemical Impedance Spectroscopy juga menunjukkan LTO/C-10%Nano Sn memiliki konduktivitas terbaik dengan nilai resistansi terkecil. ......Lithium titanate, Li4Ti5O12 (LTO) is a promising candidate as lithium ion battery anode material. LTO in nanorod structure could be even more promising as its properties are better than regular structure. In this investigation, LTO nanorod was prepared by using TiO2 powder then processed by hydrothermal method, with the help of lithium hydroxide (LiOH), resulting in LTO. Graphite and Nano Tin are mixed together with LTO using solid-state method. Three variations of Nano Tin content addition in weight%, i.e., 5, 10 and 15%, labelled as sample LTO/C-5%Nano Sn, LTO/C-10%Nano Sn and LTO/C-15%Nano Sn, respectively. The characterizations were made using XRD and SEM testing. These were performed to observe the effect of Nano Tin addition on structure and morphology of the resulting samples. The result showed that the addition of Nano-Tin of 10% (LTO/C-10%Nano Sn) has the highest specific capacity with 87.07 mAh g-1. According to Electrochemical Impedance Spectroscopy, LTO/C-10%Nano Sn also has the best conductivity with the lowest resistivity. 

Abstrak :
Gliserol merupakan senyawa organik yang dihasilkan dari trigliserida. Konversi gliserol menjadi hidrokarbon aromatik dapat meningkatkan nilai jual gliserol. Uji reaksi gliserol menjadi hidrokarbon aromatik berkatalis zeolit sintesis dilakukan dengan variasi suhu reaksi dan jenis zeolit sintesis yang digunakan. Zeolit disintesis menggunakan 20% template MDEA, EDA, dan ALS menghasilkan luas permukaan masing-masing sebesar 163,550, 30,116, dan 16,388 m2/g dengan rasio massa katalis: umpan 1:3. Uji reaksi katalitik gliserol dengan zeolit sintesis dilakukan dengan variasi suhu reaksi 420, 440, 460, dan 480 menghasilkan persen konversi gliserol dan persen selektivitas hidrokarbon aromatik. Hasil penelitian ini menunjukkan bahwa pemanfaatan gliserol menjadi hidrokarbon aromatik untuk menghasilkan senyawa aditif menggunakan katalis hasil sintesis dapat dilakukan. Hasil konversi dan selektivitas paling tinggi didapat pada kondisi suhu reaksi 480 dengan menggunakan zeolit sintesis template 20% MDEA. Persen konversi mencapai 84% dan persen selektivitas hidrokarbon mencapai 12%. ......Glycerol is an organic compound which is produced from triglycerides. Conversion into aromatic hydrocarbons can increase the sale value of glycerol. Reaction test of glycerol reaction conversion into aromatic hydrocarbons catalyzed with various synthesic zeolite with the variation of temperature is conducted. Zeolite was synthesized using 20% MDEA, 20% EDA, and 20% ALS templates producing surface area 163,550, 30,116, and 16,388 m2/g respectively. Catalytic reaction test of glycerol with synthetic zeolite was carried out with variations of temperature 420, 440, 460, and 480 ℃ and with a mass ratio of catalyst: feed 1:3 resulting in the percent conversion of glycerol and percent selectivity of aromatic hydrocarbons. The results of this study indicate that the use of glycerol to obtain aromatic hydrocarbons is viable. Conversion and selectivity results obtained at the highest temperature of the reaction conditions of 480 ℃ using zeolite synthesis templates 20% MDEA. Percent conversion obtained was 84% and the percent of aromatic hydrocarbon selectivity reached 12%.