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"Studi Kinetika reaksi hidrogenasi C02 menjadi metanol dengan basis katalis oksida Iogam Cu da.n campuran lainnya sudah banyak dilakukan oleh para peneliti sebelumnya. Keanekaragaman Percobaan yang telah dilakukan menghasilkan berbagai jenis mekanisme reaksi dan persamaan kinetika yang bervariasi. Pada penelitian kali ini katalis yang digunakan adalah CuO/Zn0/A1103/Cr1O3 dengan luas permukaan katalis sebesar 25 m2/gr. Untuk mencegah terjadinya difusi intemal dan difusi ekstemal pada pengambilan data kinetika, maka dilakukan percobaan pendahuluan menggunakan diameter katalis berkisar antara 0,125 - 0,25 mm dan laju alir umpan di atas 100 ml/menit. Penentuan persarnaan laju reaksi dilakukan dengan analisis kinetika adsorpsi isotermal berdasarkan asumsi mekanisme reaksi Coterorzm, sehingga diperoleh persamaan laju pembentukkan metanol adalah sebagai berikut : rM = (0,3075)Pco2Ph2 / 1 + 0.5516Pco2 - 1,18417Pco2Ph2"

"ABSTRACTThe construction and excitation circuit of carbon dioxide laser 616 mm long is described. The dependence of the pulse emission energy on the energy supplied to the discharge, the pressure and composhdon gaseous mixture is presented. The emission energy is 1-2 Joules. The emission pulse isexpected to cover range from 100 ns - 200 ns."

"Elektroreduksi CO2 merupakan teknik yang menjanjikan karena dapat mengkonversi CO2 secara langsung menjadi hidrokarbon. Penggunaan elektroda Cu dan boron-doped diamond (BDD) dalam proses elektroreduksi CO2 dilaporkan mampu menghasilkan konversi CO2 menjadi turunan hidrokarbon secara efisien. Pada penelitian ini, deposisi Cu2O ke permukaan BDD dan Cu dilakukan guna meningkatkan sifat katalitik BDD, sekaligus mempelajari jenis spesi Cu yang paling berperan dalam reaksi elektroreduksi CO2. Deposisi elektroda dilakukan dengan menggunakan teknik amperometri. Pada setiap elektroda dilakukan karakterisasi dengan menggunakan instrumentasi Scanning Electron Microscope (SEM), Energy Dispersive Spectroscopy (EDS), X-Ray Photoelectron Spectroscopy, dan Cyclic Voltammetry (CV). Elektroreduksi dilakukan dalam sistem dua  kompartemen berbentuk H dengan menggunakan larutan NaCl 0.1 M yang ditempatkan di katoda serta Na2SO40.1 M ditempatkan di anoda. Elektroreduksi dilakukan dengan menggunakan sistem kerja tiga elektroda yang terdiri dari elektroda kerja, elektroda pendukung berupa kawat Pt, serta elektroda pembanding Ag/AgCl pada variasi potensial -1.0 V dan -1.5 V selama 60 menit. Produk hasil reduksi dianalisa dengan menggunakan High Performance Liquid Chromatograph (HPLC) dan Gas Chromatography (GC) untuk produk liquid serta untuk untuk produk gas menggunakan Gas Chromatography (GC) dengan detektor TCD. Elektroda Cu2O-BDD menghasilkan produk yang paling bervariasi dibandingkan dengan elektroda lainnya dengan produk hasil berupa asam format, etanol, dan asam asetat. Produk dengan jumlah  paling banyak dihasilkan adalah asam asetat dengan jumlah 29,8 mg/L dengan persen (%) efisiensi faraday sebesar 68,2  % oleh elektroda Cu2O-BDD pada potensial -1.5 V.

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CO2 Electroreduction is a promising technique in CO2 reduction because it can converts CO2 directly into hydrocarbon. The uses of Cu and Boron-Doped Diamond as working electrode in CO2 electroreduction is reported to be able converting CO2 into hydrocarbon derivative efficiently. In this research, Cu2O deposited into BDD and Cu surfaces to increase the BDD catalytic activity and study which Cu has the biggest role in electroreduction CO2 process. Deposition of the material into electrode surface is done using amperometry technique. Each electrode characterized using Scanning Electron Microscopy (SEM), Energy Dispersive Spectroscopy (EDS), and X-Ray Photoelectron Spectroscopy, and Cyclic Voltammetry (CV) instrumentation. Electroreduction process is done using  two compartment system with H-shaped using NaCl solution 0.1 M in cathode and Na2SO4 in anode. Electroreduction performed using three electrode system, which are working electrode, Pt mesh as counter electrode, and Ag/AgCl as reference electrode with -1,0 V and -1,5 V potential in 60 minutes. The resulting product is analyzed using High Performance Liquid Chromatograph (HPLC) and Gas Chromatography (GC) for liquid product and GC with TCD detector for the gas product. The reduction process using Cu2O-BDD as working electrode produced more variative products other than the other electrodes, which are formic acid, ethanol, and acetic acid. The most produced product from the process is acetic acid with in concentration 29,8 mg/L and %faradaic efficiency 68,2% using Cu2O-BDD electrode in -1,5 V potential."

"Many applications and industrial processes require very low cooling temperature, such as cold storage in the biomedicalfield, requiring temperature below -80 °C. However, single-cycle refrigeration systems can only achieve the effectivecooling temperature of -40 °C and, also, the performance of the cycle will decrease drastically for cooling temperatureslower than -35°C. Currently, most of cascade refrigeration systems use refrigerants that have ozone depletion potential(ODP) and global warming potential (GWP), therefore, in this study, a cascade system is simulated using a mixture ofenvironmentally friendly refrigerants, namely, carbon dioxide and a hydrocarbon (propane, ethane or ethylene) as therefrigerant of the low temperature circuit. A thermodynamic analysis is performed to determine the optimal compositionof the mixture of carbon dioxide and hydrocarbons in the scope of certain operating parameters. In addition, aneconomic analysis was also performed to determine the annual cost to be incurred from the cascade refrigeration system.The multi-objective/thermoeconomic optimization points out optimal operating parameter values of the system, toaddressing both exergy efficiency and its relation to the costs to be incurred."

"Peningkatan konsentrasi karbon dioksida (CO2) di atmosfer meningkatkan penyerapan panas dan memancarkan panas, sehingga membuat bumi menjadi lebih hangat. Untuk mengurangi dampak CO2, dilakukan usaha-usaha untuk konversi CO2 menjadi bahan bakar atau bahan baku kimia yang lebih bermanfaat. Konversi CO2 menjadi bahan bakar dan bahan kimia dengan metode elektrokimia dianggap menjanjikan karena elektroreduksi CO2 dapat dilakukan pada tekanan dan suhu atmosfer sehingga ideal untuk diaplikasikan dalam skala besar. Tembaga merupakan salah satu logam yang dapat mengkatalisis reduksi CO2 secara elektrokimia menjadi berbagai produk seperti CO, metana, asam format, etanol, etilena dan hidrokarbon yang lebih tinggi. Aktivitas dan selektivitas busa tembaga diharapkan dapat meningkat dengan memodifikasi busa tembaga menggunakan metal organic framework (MOF) untuk memperoleh luas permukaan aktif elektroda yang lebih besar serta menurunkan perbedaan energi antara CO2 dan intermedietnya sehingga proses elektroreduksi CO2 dapat berlangsung lebih efektif. Pada penelitian ini, dilakukan modifikasi elektroda busa tembaga dengan Cu-MOF-74 menggunakan metode solvotermal. Karakterisasi dengan menggunakan X-Ray Diffraction (XRD) mengonfirmasi keberhasilan sintesis Cu-MOF-74 di atas permukaan busa tembaga. Selain itu, hasil karakterisasi Scanning Electron Microscope-Energy-Dispersive X-Ray (SEM-EDX) juga mengkonfirmasi adanya Cu-MOF-74 pada permukaan busa tembaga dengan diameter pori 27,1 mm.Selanjutnya dilakukan reduksi elektrokimia CO2 menggunakan sistem flow cell dengan laju alir elektrolit 75 mL/menit dan potensial -1,3 V; -1,5 V; -1,7 V; dan -1,9 V (vs Ag/AgCl). Efisiensi Faraday dihitung dari produk utama (asam format dan hidrogen) dengan menggunakan elektroda Cu@Cu-MOF-74, diperoleh EF sebesar 72,30% untuk asam format dan 68,57% untuk hidrogen, lebih tinggi apabila dibandingkan dengan elektroda busa tembaga yang memperoleh nilai efisiensi Faraday asam format tertinggi sebesar 56,29% dan 63,63% untuk hidrogen.

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Carbon dioxide (CO2) is a greenhouse gas that absorbs and emits heat, which also warms the earth. To reduce these negative impacts, it is necessary to convert CO2 into fuel or chemical raw materials that are more useful. The conversion of CO2 into fuels and chemicals by the electrochemical method is considered promising because the electroreduction of CO2 can be carried out at atmospheric pressure and temperature making it ideal for large-scale applications. Copper foam is a metal that can catalyze the electrochemical reduction of CO2 into various products such as CO, methane, formic acid, ethanol, ethylene and higher carbon. The activity and selectivity of copper foam is expected to increase by modifying the copper foam using a metal organic framework (MOF) to obtain a larger active electrode surface area and reduce the energy difference between CO2 and its intermediary so that the CO2 electroreduction process can take place more effectively. In this study, modification of copper foam electrodes will be carried out using the Cu-MOF-74 with solvothermal method. The physical characterization of the electrode using X-Ray Diffraction (XRD) confirmed that Cu MOF-74 has been successfully synthesized on the surface of copper foam. In addition, the results of the Scanning Electron Microscope-Energy-Dispersive X-Ray (SEM-EDX) characterization also confirmed the presence of Cu-MOF-74 on the surface of copper foam with a pore diameter of 27,1 mm. Furthermore, electrochemical reduction of CO2 was carried out using a flow cell system with a flow rate of 75 mL/minute and a potential of -1.3 V; -1.5V; -1.7V; and -1.9 V (vs Ag/AgCl). Faraday efficiency was calculated from the main products (formic acid and hydrogen) using Cu@Cu-MOF-74 electrodes, obtained an EF of 72.30% for formic acid and 68.57% for hydrogen, higher when compared to copper foam electrodes which obtained the highest Faraday efficiency values for formic acid of 56.29% and 63.63% for hydrogen."

"Karbon dioksida (CO2) merupakan gas rumah kaca yang berperan penting dalam peningkatan suhu bumi yang memicu terjadinya pemanasan global. Untuk mengurangi konsentrasi CO2, harus dilakukan konversi CO2 menjadi produk yang memiliki nilai tambah. Pada penelitian ini, metode fotoelektrokimia digunakan untuk mengkonversi CO2 dalam bentuk bikarbonat menggunakan fotokatoda CuBi2O4 yang telah dimodifikasi dengan nanopartikel perak. CuBi2O4 disintesis dengan metode solvotermal dan nanopartikel perak disintesis dengan menggunakan kompleks asam tanat dan natrium sitrat. Fabrikasi fotokatoda dilakukan menggunakan metode doctor blade pada FTO 1x1 cm2. Fotokatoda dimodifikasi menggunakan nanopartikel perak dengan variasi waktu pencelupan yaitu 10s, 30s, dan 50s. Berdasarkan karakterisasi UV-Vis DRS, energi celah pita FTO/CBO (1,77 eV) menurun setelah dimodifikasi dengan nanopartikel perak menjadi 1,71 eV. Hal ini menunjukkan bahwa modifikasi nanopartikel perak dapat memengaruhi sifat elektronik dari semikonduktor CuBi2O4. Pengujian fotoelektrokimia dilakukan dengan sistem tiga elektroda dengan metode linear sweep voltammetry (LSV) dan chronoamperometry (transient chopped light photocurrent) selama 120 detik dengan mati nyala lampu setiap 10 detik. Didapatkan fotokatoda FTO/CBO/Ag 30s memiliki performa yang paling baik, yaitu memiliki onset potensial sebesar -0,008 V, densitas arus sebesar -12,859 mA/cm2 dengan stabilitas foto arus tertinggi yaitu 84,4%.

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Carbon dioxide (CO2) is a greenhouse gases that has an important role in increasing the average temperature of the earth which triggers global warming. In order to reduce the concentration of CO2, it is necessary to convert CO2 into other products that have added value. In this experiment, a photoelectrochemical method was used to convert CO2 in the form of bicarbonate into formic acid using CuBi2O4 photocathode that had been modified with silver nanoparticles. CuBi2O4 was synthesized by solvotermal method and silver nanoparticles were synthesized using a complex of tannic acid and sodium citrate. Fabrication of photocathode was carried out using the doctor blade method with FTO 1x1 cm2. The photocathode was modified using silver nanoparticles with variations in immersion time of 10s, 30s, dan 50s. Based on the UV-Vis DRS characterization, band gap energies of FTO/CBO (1.77 eV) decreased after being modified with silver nanoparticles to 1.71 eV. This data indicates that the modification of silver nanoparticles can affect the electronic properties of the CuBi2O4 semiconductor. Photoelectrochemical testing was carried out with a three-electrode system with linear sweep voltammetry and chronoamperometry (transient chopped light photocurrent) methode for 120 seconds with chopped light every 10 seconds. It was found that the FTO/CBO/Ag 30s photocathode has the best performance, which has an onset potential of -0.008 V, a current density of -12,859 mA/cm2 with the photocurrent stability of 84.4%."

"Carbon Capture and Storage, Second Edition, provides a thorough, non-specialist introduction to technologies aimed at reducing greenhouse gas emissions from burning fossil fuels during power generation and other energy-intensive industrial processes, such as steelmaking. Extensively revised and updated, this second edition provides detailed coverage of key carbon dioxide capture methods along with an examination of the most promising techniques for carbon storage. The book opens with an introductory section that provides background regarding the need to reduce greenhouse gas emissions, an overview of carbon capture and storage (CCS) technologies, and a primer in the fundamentals of power generation. The next chapters focus on key carbon capture technologies, including absorption, adsorption, and membrane-based systems, addressing their applications in both the power and non-power sectors. New for the second edition, a dedicated section on geological storage of carbon dioxide follows, with chapters addressing the relevant features, events, and processes (FEP) associated with this scenario. Non-geological storage methods such as ocean storage and storage in terrestrial ecosystems are the subject of the final group of chapters. A chapter on carbon dioxide transportation is also included. This extensively revised and expanded second edition will be a valuable resource for power plant engineers, chemical engineers, geological engineers, environmental engineers, and industrial engineers seeking a concise, yet authoritative one-volume overview of this field. Researchers, consultants, and policy makers entering this discipline also will benefit from this reference"