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"[ABSTRAKDeposit ampas tebu di Indonesia yang mencapai 8,5 juta ton per tahun menjadikan biomassa ini potensial untuk dikembangkan sebagai pensubstitusi bahan bakar minyak berbasis crude oil. Gelombang mikro merupakan salah satu metode pemanasan yang lebih efisien untuk mempirolisis biomassa, karena metode ini memanfaatkan prinsip konversi energi dan partikel biomassa mengalami pemanasan volumetrik. Ampas tebu dipirolisis dengan variasi daya gelombang mikro sebesar 380, 620, dan 850 Watt dan variasi bio-char dalam umpan sebanyak 0, 10, dan 20%. Karakterisasi yang dilakukan meliputi profil suhu pirolisis, yield produk pirolisis, dan kandungan senyawa di bio-oil dengan metode GC/MS. Peningkatan daya gelombang mikro akan meningkatkan laju pemanasan dan suhu pirolisis ampas tebu, walaupun efeknya tidak terlalu signifikan jika umpannya tidak ditambahkan bio-char. Penambahan bio-char sebagai absorber gelombang mikro secara signifikan meningkatkan laju pemanasan dan suhu pirolisis ampas tebu. Yield bio-oil maksimum, yaitu 42,75 dan 42,40%, diperoleh pada laju pemanasan 805oC/menit dan suhu pirolisis 515oC serta laju pemanasan 59oC/menit dan suhu pirolisis 398oC. Kondisi operasi untuk memperoleh kedua parameter laju pemanasan dan suhu pirolisis tersebut adalah daya gelombang mikro sebesar 380 Watt dengan 20% kandungan bio-char di umpan serta daya gelombang mikro sebesar 850 Watt tanpa kandungan bio-char di umpan. Bio-oil yang diperoleh dari pirolisis ampas tebu yang umpannya mengandung bio-char ternyata mengandung lebih banyak senyawa non-oksigenat dan tidak mengandung PAH. Namun, senyawa non-oksigenat tersebut juga memiliki kandungan rantai karbon panjang (C22+) yang cukup tinggi.

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ABSTRACTSugarcane bagasse waste in Indonesia reaching 8.5 million tons per year is potential to be developed as a substituent for petroleum-based fuel oil. Microwave is an efficient heating method for biomass pyrolysis, since this method utilizes the principle of energy conversion and biomass undergoes volumetric heating. Sugarcane bagasse was pyrolyzed at the microwave power variation of 380, 620, and 850 Watt and bio-char loading variation of 0, 10, and 20%. Characterizations were conducted on the pyrolysis temperature profile, pyrolysis products yield, and bio-oil content by GC/MS method. The microwave pyrolysis of sugarcane bagasse gave results that increasing microwave power would increase the heating rate and pyrolysis temperature, however this phenomenon was insignificant if the feed contained no bio-char. The addition of bio-char as microwave absorber in the feed significantly increased the heating rate and temperature pyrolysis. The highest bio-oil yields, i.e. 42.75 and 42.40%, were obtained at the heating rate of 805oC/min and pyrolysis temperature of 515oC and heating rate of 59oC/min and pyrolysis temperature of 398oC. Those pyrolysis heating rates and temperatures were achieved at the microwave power of 380 Watt with bio-char loading of 20% and the microwave power of 850 Watt with no bio-char loading. Bio-oil derived from the microwave pyrolysis of sugarcane bagasse which had no bio-char loading in fact contained more non-oxygenated compounds and less PAHs. However, those non-oxygenated compounds have a quite high content of long carbon chains (C22+).;Sugarcane bagasse waste in Indonesia reaching 8.5 million tons per year is potential to be developed as a substituent for petroleum-based fuel oil. Microwave is an efficient heating method for biomass pyrolysis, since this method utilizes the principle of energy conversion and biomass undergoes volumetric heating. Sugarcane bagasse was pyrolyzed at the microwave power variation of 380, 620, and 850 Watt and bio-char loading variation of 0, 10, and 20%. Characterizations were conducted on the pyrolysis temperature profile, pyrolysis products yield, and bio-oil content by GC/MS method. The microwave pyrolysis of sugarcane bagasse gave results that increasing microwave power would increase the heating rate and pyrolysis temperature, however this phenomenon was insignificant if the feed contained no bio-char. The addition of bio-char as microwave absorber in the feed significantly increased the heating rate and temperature pyrolysis. The highest bio-oil yields, i.e. 42.75 and 42.40%, were obtained at the heating rate of 805oC/min and pyrolysis temperature of 515oC and heating rate of 59oC/min and pyrolysis temperature of 398oC. Those pyrolysis heating rates and temperatures were achieved at the microwave power of 380 Watt with bio-char loading of 20% and the microwave power of 850 Watt with no bio-char loading. Bio-oil derived from the microwave pyrolysis of sugarcane bagasse which had no bio-char loading in fact contained more non-oxygenated compounds and less PAHs. However, those non-oxygenated compounds have a quite high content of long carbon chains (C22+)., Sugarcane bagasse waste in Indonesia reaching 8.5 million tons per year is potential to be developed as a substituent for petroleum-based fuel oil. Microwave is an efficient heating method for biomass pyrolysis, since this method utilizes the principle of energy conversion and biomass undergoes volumetric heating. Sugarcane bagasse was pyrolyzed at the microwave power variation of 380, 620, and 850 Watt and bio-char loading variation of 0, 10, and 20%. Characterizations were conducted on the pyrolysis temperature profile, pyrolysis products yield, and bio-oil content by GC/MS method. The microwave pyrolysis of sugarcane bagasse gave results that increasing microwave power would increase the heating rate and pyrolysis temperature, however this phenomenon was insignificant if the feed contained no bio-char. The addition of bio-char as microwave absorber in the feed significantly increased the heating rate and temperature pyrolysis. The highest bio-oil yields, i.e. 42.75 and 42.40%, were obtained at the heating rate of 805oC/min and pyrolysis temperature of 515oC and heating rate of 59oC/min and pyrolysis temperature of 398oC. Those pyrolysis heating rates and temperatures were achieved at the microwave power of 380 Watt with bio-char loading of 20% and the microwave power of 850 Watt with no bio-char loading. Bio-oil derived from the microwave pyrolysis of sugarcane bagasse which had no bio-char loading in fact contained more non-oxygenated compounds and less PAHs. However, those non-oxygenated compounds have a quite high content of long carbon chains (C22+).]"

"Industri tekstil menghasilkan air limbah paling banyak, terhitung hampir setengah dari semua limbah pewarna diseluruh dunia. Sumber masalahnya pewarna yang digunakan adalah pewarna sintesis dimana dari senyawa azo sekitar 60-70%. Senyawa azo adalah senyawa organik dengan gugus -N=N- bersifat stabil sehingga sulit untuk degradasi dalam sistem akuatik. Hingga saat ini, adsorpsi dianggap sebagai salah satu teknik yang paling unggul untuk penghilangan zat warna dalam sistem akuatik. Pada penelitian ini, peniliti mensintesis komposit KGC-Fe3O4 sebagai adsorben zat warna Methylene Blue dan Rhodamine B. Hasil sintesis kemudian dikarakterisasi menggunakan beberapa intstrumentasi yaitu, FTIR, XRD, SEM-EDX, dan BET. Hasil sintesis diaplikasikan untuk melihat pH, waktu kontak, konsentrasi adsorbat, dan jumlah adsorben optimum. Selanjutnya, KGC-Fe3O4 diuji reusabilitas dan dilihat perbandingan selektivitasnya terhadap dua zat warna kationik.......The textile industry generates the most amount of wastewater, accounting for nearly half of all dye waste worldwide. The source of the problem is the dyes used are synthetic dyes which contain about 60-70% of azo compounds. Azo compounds are organic compounds with -N=N- groups which are stable, making it difficult to degrade in aquatic systems. Until now, adsorption is considered as one of the most superior techniques for dye removal in aquatic systems. In this study, the researchers synthesized the KGC-Fe3O4 composite as an adsorbent for Methylene Blue and Rhodamine B dyes. The results of the synthesis were then characterized using several instruments, namely FTIR, XRD, SEM-EDX, and BET. The synthesis results were applied to see the optimum pH, contact time, adsorbate concentration, and amount of adsorbent. Next, KGC-Fe3O4 was tested for reusability and a comparison of its selectivity was observed for the two cationic dyes."

"Pemanfaatan limbah menjadi alat yang bernilai guna sangat penting bagi lingkungan. Limbah tempurung kelapa dapat diolah sebagai sumber karbon untuk kemudian disintesis menjadi bahan aktif untuk aplikasi elektroda superkapasitor. Tujuan dari penelitian ini untuk mengetahui pengaruh kondisi impregnasi logam, suhu pirolisis, dan suhu aktivasi tempurung kelapa terhadap kinerja superkapasitor. Elektroda superkapasitor dirangkai dengan elektrolit berupa KOH 3 M, binder berupa PVA dengan campuran asam sitrat sebagai crosslinking agent, dan separator berupa kertas saring. Hasil penelitian terbaik berdasarkan uji Cyclic Voltammetry diperoleh sampel Ni10-P550-A700. Hal ini menunjukkan bahwa suhu pirolisis (550oC) dan aktivasi tertinggi (700oC) dapat berpengaruh terhadap hasil nilai kapasitansi tertinggi yaitu sebesar 165,75 F/g. Hasil perhitungan energi aktivasi menghasilkan nilai Ea terkecil yaitu 3,88 kJ/mol sehingga menandakan bahwa keberadaan logam dapat berperan sebagai katalis pada proses pirolisis. Karakterisasi BET pada bio-char menunjukkan luas permukaan spesifik sebesar 257,7 m2/g. Sementara itu, hasil karakterisasi SEM memperlihatkan permukaan char dengan persebaran pori yang banyak. Kemudian, hasil karakterisasi dengan Spektrofotometri UV-Vis memberikan hasil bahwa sampel Ni10-P550-A700 memiliki sifat konduktor. Oleh karena itu, seluruh hasil karakterisasi menunjukkan bahwa limbah tempurung kelapa hasil pirolisis dapat berfungsi sebagai penyimpan energi yang baik.......Recycling waste into usable devices is essential for the environment. Coconut shell waste can be processed as a carbon source and synthesized into active ingredients for supercapacitor electrode applications. This study aimed to determine the effect of metal impregnation conditions, pyrolysis temperature, and coconut shell activation temperature on supercapacitor performance. Supercapacitor electrodes are assembled with electrolyte KOH 3 M, binder in the form of PVA with a mixture of citric acid as a crosslinking agent, and separator using filter paper. The Ni10-P550-A700 sample obtained the best research results from the Cyclic Voltammetry test. This result shows that the pyrolysis temperature (550o

"Dalam rangka untuk menghasilkan minyak diesel sintetis dan bahan kimia lain melalui reaksi Fischer-Tropsch, maka perlu untuk dipersiapkan gas sintesis yang H2/CO rasio mol-mendekati 2 sebagai umpan. Produksi gas sintesis ini dilakukan dengan melibatkan reaksi oksidasi parsial metana menggunakan oksigen murni dibuat dari pemurnian udara sehingga membuat reaksi ini cukup mahal. Reaksi alternatif yang diusulkan untuk mengurangi biaya penyediaan oksigen murni adalah dengan mengganti sumber oksigen yang disediakan oleh mineral CaO dalam arang batubara yang dipreparasi dengan pertukaran antara ion-ion Ca2+ dengan gugus fungsi karboksilat yang telah tersedia dalam batubara lignit dilanjutkan pirolisis batubara. Reaksi oksidasi parsial antara CaO dengan metana telah dilakukan dengan variasi suhu pirolisis suhu 700, 800 dan 900°C dan suhu reaksi oksidasi 700, 800 dan 900°C. Produk ini mengandung gas yang didominasi H2 dan CO. Pada sebagian besar produk, komposisi H2 menurun dengan waktu reaksi sedangkan komposisi CO meningkat terhadap waktu reaksi hal ini disebabkan adanya reaksi perengkahan metana yang menyebabkan terjadinya deposisi karbon dan kemungkinan terjadinya reaksi water gas shift yang bergeser kearah pembentukkan CO. Adapun kondisi optimum yang diperoleh dalam produksi gas sintesis dalam penelitian ini adalah pada suhu pirolisis 700°C dan suhu reaksi 800°C dengan rasio H2/CO yang berada pada rentang 3,85 - 2,1. ......In order to produce synthetic diesel oil and most chemicals through Fischer-Tropsch reaction, it is required to prepare synthesis gas whose H2/CO mole-ratio close to 2 as a feed stock for the reaction. Conventionally, the production of this synthesis gas uses partial oxidation reaction involving methane and pure oxygen prepared from purification of air which makes this reaction quite expensive. An alternative reaction is proposed to reduce the cost in which oxygen instead is supplied by CaO mineral in the coal char prepared by ion-exchange between ions Ca2+ and carboxylic functional group already available in the lignite coal and pyrolysis of the coal. Partial oxidation reaction between CaO with methane has been has been done on variations of temperature pyrolysis 700, 800 and 900°C and the reaction temperature oxidation (700, 800 and 900°C). This product contains predominantly gas H2 and CO in most combinations H2/CO ratio decreased with reaction time. The optimum condition obtained in production of synthesis gas is at a temperature pyrolisis of 700 _C and reaction temperature of 800°C with H2/CO ratio produced in these condition is in range 3,85 to 2,1."

"Dewasa ini kebutuhan akan bahan bakar minyak di Indonesia semakin meningkat. Namun, hal ini tidak disertai dengan peningkatan produksi minyak. Salah satu cara untuk memproduksi minyak adalah dengan menggunakan batubara lignit dalam proses gasifikasi untuk membentuk syngas yang kemudian digunakan untuk mensintesis bahan bakar. Untuk mendapatkan rasio H2/CO yang sesuai pada proses gasifikasi, diperlukan char yang memiliki luas permukaan yang besar. Char yang memiliki luas permukaan besar dapat dihasilkan dari proses pirolisis batubara lignit. Penelitian ini bertujuan untuk mengetahui kondisi pirolisis yang terbaik untuk mendapatkan char dengan luas permukaan yang terbesar. Pada penelitian ini, pirolisis dilakukan dengan variasi suhu 700, 775, 800 °C dan laju pemanasan 3, 6, dan 9 °C. Pada akhir penelitian, didapatkan bahwa laju pemanasan dan suhu akhir pirolisis memiliki korelasi positif dengan pengurangan massa char. Suhu akhir pirolisis memiliki korelasi positif dengan luas permukaan char dan laju pemanasan memiliki korelasi negatif dengan luas permukaan char. Akhirnya dihasilkan char dengan luas permukaan tertinggi yaitu 172 m2/gram dari pirolisis dengan suhu akhir 850 °C dan laju pemanasan 3 °C/menit.

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Recently, Indonesia’s fossil fuels requirement is increasing. This increase is not accompanied by oil and gas production. One method to produce fuels is by gasifying lignite coal into synthetic gas and do a Fischer-Tropsch process on synthetic gas. To produce synthetic gas with convenient H2/CO ratio for Fischer-Tropsch process, the coal used must be has large surface area which can be achieved by pyrolysis process.

This research aims to identify the best condition that produces char with the largest surface area. Final temperature variation used is 700, 775, 850 °C with heating rate variation of 3, 6, and 9 °C/minute. In this research it was found that increase of final temperature and heating rate would increase weight loss of the char. Increase of final temperature would increase char surface area. Increase of heating rate would decrease char surface area.

At the end of the research, char with the largest surface area produced is 172 m2/gram which is produced in final temperature of 850 °C and heating rate of 3 °/minute."

"Agricultural waste hasincreased colossally with development in agricultural production causing environmentalnuisance and degradation. Utilization of coconut husks, one of such type of waste, as a biosorbent for polluted surface water treatment, wasconsidered in this study. Polluted surface water was gently passed through twosimilar columns loaded with 100 and 200 g of coconut husk char respectively.The treated water samples collected after 30, 60, 90, 120 and 150 mins wereexamined for SO42-, NO3- and PO43-ions concentration. Removal efficiency for SO42-, NO3-and PO43- ions on 100 g coconut husk char after 150mins detention time were 70, 78 and 91% respectively. Freundlich isotherm modelgave a better description of the data (R2 > 0.96). Sorption datawas well described by second order pseudo kinetics (R2 >0.85). An amount of 100 g of the biosorbenthas astrong affinity for these types of ion removal in contaminated water. Coconut huskchar as a biosorbentis a panacea to significant concentrations of polyatomic ions in polluted surface water."

"Agricultural waste has increased colossally with development in agricultural production causing environmental nuisance and degradation. Utilization of coconut husks, one of such type of waste, as a biosorbent for polluted surface water treatment, was considered in this study. Polluted surface water was gently passed through two similar columns loaded with 100 and 200 g of coconut husk char respectively. The treated water samples collected after 30, 60, 90, 120 and 150 mins were examined for SO42-, NO3- and PO43- ions concentration. Removal efficiency for SO42-, NO3- and PO43- ions on 100 g coconut husk char after 150 mins detention time were 70, 78 and 91% respectively. Freundlich isotherm model gave a better description of the data (R2 > 0.96). Sorption data was well described by second order pseudo kinetics (R2 > 0.85). An amount of 100 g of the biosorbent has a strong affinity for these types of ion removal in contaminated water. Coconut husk char as a biosorbent is a panacea to significant concentrations of polyatomic ions in polluted surface water."

"Gas sintesis dapat dibuat menjadi bahan bakar cair seperti minyak bumi, minyak disel dan bahan-bahan bakar lainnya melalui reaksi Fischer-Tropsch. Produksi gas sintesis ini dilakukan dengan melibatkan reaksi oksidasi parsial metana dengan menggunakan proses Chemical Looping Reforming menggunakan oksida logam CaO sebagai oksigen pembawa untuk menggantikan oksigen murni yang sangat mahal. Sumber oksigen yang disediakan oleh CaO dalam char batubara yang dipreparasi dengan pertukaran antara ion-ion Ca2+ dan gugus fungsi karboksilat pada kondisi pH 8,3 yang telah tersedia dalam batubara lignit dan pirolisis batubara reaksi oksidasi parsial antara CaO dengan metana telah dilakukan pada variasi suhu pirolisis suhu 700, 800 dan 900°C dan suhu reaksi oksidasi (700, 800 dan 900°C). Kemungkinan reaksi yang terjadi pada arang CaO adalah reaksi perengkahan metana, water gas shift reaction dan parsial oksidasi metana. Adapun kondisi optimum yang diperoleh dalam produksi gas sintesis adalah pada suhu pirolisa 700°C dan suhu reaksi 700°C dengan rasio H2/CO yang dihasilkan pada kondisi tersebut berada pada rentang 0,642-2,387. ......Synthesis gas can be made into liquid fuels such as oil, diesel oil and fuel materials other via Fischer-Tropsch reaction. Synthesis gas production is done by involving the partial oxidation of methane by using chemical looping reforming process using metal oxide CaO as the oxygen carrier to replace the expensive pure oxygen. Oxygen source provided by CaO in the coal char is prepared by ion exchange between the ions Ca2+ and carboxylate functional groups on the condition of pH 8,3 is already available in the lignite and coal pyrolysis of coal. Partial oxidation reaction of CaO with methane has been done on variations in temperature pyrolysis temperature 700 , 800 and 900°C and the reaction temperature oxidation (700, 800 and 900°C). Possible reactions that occur in the reaction of CaO char is methane cracking, water gas shift reaction and partial oxidation methana. The optimum conditions obtained in the production of synthesis gas is at a temperature pyrolisis of 700°C and reaction temperature to 900_C H2/CO ratio produced in these conditions is in the range 0,642-2,387."