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Global warming has become an increasingly important issue around the world today due to the rise of anthropogenic greenhouse gases emission, which gives several negative impacts on human life. There are some techniques have been studied and assessed i.e. physical mechanism by injected CO2 to the geological formations, chemical mechanism with artificial tree technology and biological mechanism by increasing the primary production through iron enrichment in high nutrient-low chlorophyll (HNLC) waters as well as mixing of water column below the sea surface. Those technologies, which are well known as Carbon Capture Storage ‘(CCS) technology, are expected to be applied to reduce the oncentration of anthropogenic CO2 in the atmosphere and to minimize the global warming. The Center of Environmental Technology, Agency for the Assessment and Application of Technology (BPPT) will carry out a research concerning CO2 reduction by a phytoplankton culture in a photobioreactor in three years. The main objective of this research is to assess the CO2 uptake capability of tropical phytoplankton. In this paper, we would showed the creteria and design to assembly a photobioreactor esspesially a air lift photobioreactor. To improve performance photobioreaktor, the materials included design criteria and the dynamics of fluids in fotobioreaktor have to considered propoerly. Other the hand, the selection of the most productive species and selection of appropriate media and economically also important to be done.

- Source of electrical energy is currently the main problems in Singkawang city, this is because the number of population density increased annually. Besides, the problem of the amount of waste continues to rise, these two problems can be solved with one solution to convert a renewable energy that makes a potential where trash converted into power plant of waste to energy. To determine whether the waste can be a solution to the energy crisis by conducting a study of potential waste or garbage into fuel power plant. writing this essay described how rubbish can produce electrical energy for 24833.76 kWh / day if operating for one year amounted to 9,064,322.4 kWh / year or 9064.32 MWh / year, The first step is to know the total amount of organic waste per day, the number of calories in the organic waste, the amount of energy (kWh) / day, the capacity of power generation, the power output of the boiler, steam turbine net power.

It was conducted to engineering the adsorption column by using ferro powder waste as adsorbent to removal the H2S content of biogas from Palm Oil Mill Effluent. The first step it was conducted to calculated the adsorption column as purification column by character Palm Oil Mill Effluent (POME) considering. Further, is was conducted to annealed the ferro powder from industrial waste workshop in north Sumatera. Thus, it was conducted to annealed with temperature variation (800°C, 900°C and 1000°C) and the thick adsorbent (1 cm, 2 cm).The result shows that each adsorbent product is tested by applied of using direct that puts in the adsorbent column. Applied research is conducted by flowing biogas trought column that the adsorbent is alreadyin the column. Temperature condition and the width of adsorbent was effecting of adsorption the H2S biogas and the optimal condition are 1000°C temperature and 2 cm of width adsorbance

Terjadinya Perubahan iklim pada saat ini telah mengkibatkan dampak buruk terhadap kehidupan makhluk hidup di permukaan bumi. Kekeringan, banjir atau rob, gelombang udara panas, dan badai merupakan beberapa contoh yang disebabkan oleh Perubahan iklim. Pada sektor pertanian, kondisi tersebut akan menyebabkan produksi tanaman mengalami penurunan yang cukup signifikan sehingga mengganggu ketahanan pangan nasional dan menurunkan pendapatan petani dan devisa negara. Penyebab utama terjadinya Perubahan iklim adalah meningkatnya emisi gas rumah kaca (terutama gas CO2) di udara, yang dihasilkan oleh aktivitas manusia (antropogenik). Untuk mengurangi emisi gas CO2 Pemerintah Republik Indonesia telah mencanangkan Rencana Aksi Nasional Penurunan Emisi Gas Rumah Kaca (RAN-GRK) sesuai Peraturan Presiden Nomor 61 tahun 2011. Salah satu kegiatan utamanya adalah penanaman 105.200 ha tanaman karet. Peran ekologis tanaman karet yaitu tajuknya dapat menyerap gas CO2 dari udara dan dari hasil biji karet dapat dibuat biodiesel dengan gas buang CO2 yang lebih rendah dari bahan bakar minyak (solar), sehingga tanaman karet mempunyai peran yang penting dalam mengurangi kejadian Perubahan iklim (mitigasi). Jumlah CO2 yang diserap oleh tanaman karet bervariasi tergantung kepada umur tanaman, kondisi tanaman, kesuburan tanah, dan teknis budidaya yang diterapkan. Rata-rata stok karbon pada karet tradional (perkebunan rakyat) 19,8 ton C/ha, sedangkan pada karet klon unggul (perkebunan besar) 42,4 ton C/ha. Jumlah gas CO2 yang diserap oleh perkebunan karet di Indonesia mencapai 291,16 Mton CO2e. Potensi produksi biodiesel dari RSO di Indonesia mencapai 424.460 ton. Campuran solar dan biodiesel dari RSO dapat menurunkan emisi gas buang CO2 sebesar 40,14%. Role of rubber plant in climate change mitigation Climate change happened and resulted in adverse effect of our life on the earth's surface. Droughts, floods, or rob, heatwaves, and hurricanes happened recently of incident that might be caused by climate change. In the agricultural sector, these conditions will lead to reduction of yields significantly, in turn disrupt the national food security and reduce foreign exchange. Major factor that may induce climate change is the increased greenhouse gas emissions primarily CO2 in air, generated by human activity (anthropogenic). To reduce emissions of CO2 gas, Government of Indonesia has launched the National Action Plan for Reducing Emissions of Greenhouse Gases (RAN-GRK) through Presidential Decree No. 61 of 2011. One of the main activity is the planting of 105,200 ha of rubber trees. Ecological role of the rubber plant is an sequestration CO2 from the air. Moreover, rubber yielded may be converted into biodiesel fuel having CO2 content being lower than diesel oil in otherwords, rubber plant has an important role in reducing of incidences of climate change (mitigation). The amount of CO2 is sequestrated by rubber plant varies depending on the age of the plant, crop conditions, soil fertility and technical cultivation applied. Average of carbon stock of those rubber plants cultivated traditionally was 19.8 ton C / ha, while those superior clone ones was 42.4 ton C/ha. The amount of CO2 gas sequestrated by rubber in Indonesia reached of 291.16 Mton CO2e. Potentially biodiesel production developed from the RSO in Indonesia reached 424,460 ton, blending of diesel oil and biodiesel from RSO able to reduce CO2 emissions of 40.14%.

The use of manure and litter as bio gas-producing material is one solving problem of sanitation and environmental health as well as the control of environmental pollution, especially in the vicinity of the farm and the market environment. To obtain biogas productivity and optimum quality then conducted a study with the aim to determine the effect of a composition ratio mix of fish maw, kale and feces of pigs against pH, productivity in this case, the gas pressure (Pa), gas mass (kg) and the volume of gas (m3), as well as the quality of the biogas as measured by the amount of calorific value (J), and power (watts), and the color of the flame produced. The results showed that the composition ratio of a mixture of 1: 1: 1 has the most stable pH with the average of 7. The gas pressure, gas mass and the volume of gas produced by the mixture composition ratio of 1: 1: 1 is larger than the composition ratio of a mixture of 2 : 1: 1, 1: 2: 1 and 1: 1: 2 with 3851.4 Pa gas pressure, gas mass kg 0.011568938 and 0.145424439 gas volume m3 calorific value of 19.680 kJ and 177.142 watts of power, as well as the color of the flame, produced that is blue. It can be concluded that the mixture composition ratio of 1: 1: 1 is the productivity and quality of the most optimal.

Agroindustries in general produce a large amount of organic wastewater. Until now, most of this organics waste-stream was not recovered and left to decompose anaerobically in ponds, where it emits methane, a potent greenhouse gas. By anaerobically digesting of the effluents in a suitable bioreactor, methane can be captured and used for combustion in gas engines or boilers. This way, uncontrolled methane emission from the anaerobic decomposition can be avoided and the utilization of fossil fuels can be replaced partly with the renewable biogas from the decomposition process. In addition, the approach of reducing green house gas emission is potentially to earn financial incentive through Clean Development Mechanism project. This paper demonstrates quantitatively some potential ecological and economical benefits derived from utilising agroindustrial effluents by treating it anaerobically to generate biogas (with cases of cane sugar factory, starch industry, palm oil mill, and tofu industry) . As illustration, for each ton cane sugar produced app. 15 m3 methane can be emitted from uncontrolled anaerobic degradation of it wastewater. By capturing the gas and transforming it into renewable biogas, a methane emission of equivalent to ≈ 272 kg CO2 can be avoided and an energy value of app. 427 MJ with a money value of app. Rp 59 600,- can be obtained. In addition, a financial incentive of app. Rp 14 850,- is possible to be earned from clean development mechanism (CDM) project. The ecological and financial benefits derived from anaerobic treatment of agroindustrial wastewater as indicated by this study should therefore become the driving force for the implementation of the approach.

Petroleum reserves are depleted in Indonesia along with increased fuel requirements, demanding Indonesian society to harness alternative energy, one of which is biofuel. In this study, biofuels produced from cracking fatty acids contained in Destillate Palm Fatty Acid (PFAD). PFAD converted into biofuels via catalytic cracking process using a catalyst Ni.Mo / Zeolite with reaction temperature 380 oC in a stirred batch reactor. Metal concentrations in the zeolite was varied at 0%, 0.5%, 1% and 1.5% and the variation of the reaction stirring 300 rpm, 400 rpm, 500 rpm and 600 rpm. Cracking process using nitrogen gas with a flow rate of 150 ml / min. Yield (%) of the product obtained at the maximum stirring speed of 500 rpm with a metal concentration of 1%, amounting to 71.43% or 125 ml with 31.53% biofuel conversion. The composition of biofuels on cracking products was 8.8% and 35% Gasoline Kerosene and Diesel.

Solar energy can be used for water heating by using solar water heater application. Therefore, its still needs some modification due to its low efficiency. This modification can be done by replacing the conventional plate of solar collectors into a double plate with a zig-zag pattern. The results shown that along with the decreasing of water flow rates could significantly increase the useful energy (Qu). Initial temperature of water inlet could affect the generated maximum temperature. The highest mean efficiencies of double plate solar water heater with a zig-zag grooved beams pattern of 49.11% was gained in the flow rate of 700 mL / min.

The aim of the study is to create double-function equipment comprises the use of a dryer in the rainy seasons and of water distillation in dry seasons. The main components consists of a windmill as the sources of mechanical power to move the blower or water dipper and a drying room doubling as a distilling room by solar energy.

Population growth impact on increasing the amount of waste and the fuel crisis as a source of energy. One solution to the problem of waste and energy crisis is biogas technology. Biogas is used for treating biodegradable waste because the most waste composition in Indonesia is organic waste . Biogas can be applied to organic waste that has not been utilized optimally for example eating garbage. In the manufacture of biogas needed additional treatment of water and agitation to optimize biogas production. In this study, using 10 reactors with the composition 4 kg of waste and 1.5 liter of rumen with additional variations of water as much as 6 liters, 4 liter, 2.6 liter, 1.5 liter and 0.67 liter. Five treatment reactor without agitation and agitation. The most numerous production gas in the reactor with a dilution of 2,6 liter in reactors 3 and 8 with gas production on day 18 of 0,8 liters. As for the treatment of agitation, the production of biogas in the reactor without agitation produces more gas than the reactor with agitation.