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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.

This research was funded by the Michigan Space Grant Consor-tium [NNX5AJ20H] , the Community Foundation for Muskegon County, the Grant Valley State University Presidential Research Grant, and the Michigan Chapter of the North American Lake Man-agement Society and Michigan Lakes and Streams Association Lake Research Student Grant to JLM. MV-A was supported by a Junta de Andalucia Award [P12-RNM 327] and an Universidad de Granada sabbatical aid. The authors thank Brian Scull and the Steinman Lab (Annis Water Resources Institute) for performing nutrient anal-yses and Muskegon Lake monitoring, respectively. The Muskegon lake Observatory project was supported by grants from EPA-Great Lakes Restoration Initiative [R5-GL2010-1] , Michigan Space Grant Consortium [NNX5AJ20H] , University of Michigan-Cooperative Institute for Great Lakes Research [NA12OAR4320071] , Community foundation for Muskegon County [20172151] , Edison Foundation [250695] , and the Annis Water Resources Institute to BAB. As sentinels of climate change and other anthropogenic forces, freshwater lakes are experiencing ecosystem disruptions at every level of the food web, beginning with the phytoplankton, a highly responsive group of organisms. Most studies regarding the effects of climate change on phytoplankton focus on a potential scenario in which temperatures continuously increase and droughts intersperse heavy precipitation events. Like much of the conterminous United States in 2019, the Muskegon River watershed (Michigan, USA) experienced record-breaking rainfall accompanied by unusually cool temperatures, affording an opportunity to explore how an alternate potential climate scenario may affect phytoplankton. We conducted biweekly sampling of environmental variables and phytoplankton in Muskegon Lake, a Great Lakes Area of Concern that connects to Lake Michigan. We compared environmental variables in 2019 to the previous eight years using long-term data from the Muskegon Lake Observatory buoy, and annual monitoring excursions provided historical phytoplankton data. Under cold and wet conditions, diatoms were the single dominant division throughout the entire growth season – an unprecedented scenario in Muskegon Lake. In 10 of the 13 biweekly sampling days in 2019, diatoms comprised over 75% of the phytoplankton community in the lake by count, indicating that the spring diatom bloom persisted through the fall. Additionally, phytoplankton seasonal succession and abundance patterns typically seen in this lake were absent. In a world experiencing reduced predictability, increased variability, and regional climate anomalies, studying periods of extreme weather events may offer insight into how natural systems will be affected and respond under future climate scenarios. Michigan Space Grant Consortium NNX5AJ20H Community Foundation for Muskegon County Grant Valley State University Presidential Research Grant Michigan Chapter of the North American Lake Management Society Michigan Lakes and Streams Association Lake Research Student Grant Junta de Andalucia P12-RNM 327 Universidad de Granada EPA-Great Lakes Restoration Initiative R5-GL2010-1 University of Michigan-Cooperative Institute for Great Lakes Research NA12OAR4320071 Community foundation for Muskegon County 20172151 Edison Foundation 250695 Annis Water Resources Institute

Water scarcity is a current problem in many parts of the planet and there is a worldwide concern about water availability to meet future water demand. In countries like Brazil, where most of the electricity is produced by hydroelectric power plants, water scarcity directly impacts energy production. The water–energy nexus is directly related and impacted by CO2 emissions and its climate consequences, which calls to a broader approach: energy–carbon–water nexus. In this context, the Sustainable Water and Energy Consumption (SWEC) Program was developed to mitigate water and energy supply problems in a railway company in Brazil. The actions took place in four main areas: (a) users conscientization, (b) consumption diagnosis, (c) indicators for evaluating water and energy consumption, and (d) evaluation of implementing alternative cleaner water and energy sources. The per capita consumption of water and energy were reduced by 10% and 19%, respectively. Permanent results were achieved by the SWEC Program, such as the acquisition of two photovoltaic systems with a total capacity of 96.5 kWp. The investment made provided an average monthly reduction in energy consumption of 56% in 2022. This work contributed to the UN Agenda 2030 and the findings may help companies and industries, and other institutions, such as universities and schools, to improve their water and electricity consumption.

Population growth and economic development, aggravated by climate change, will increase pressure on energy and water resources. Integrated planning can make the most of these two essential and scarce resources. Thirsty Energy, a World Bank initiative, helps countries address these issues and ensure sustainable development of both resources. This note focuses on the water needs of the power sector and particularly answers the following questions: Why is this issue important? Do power plants need all that much water? What about other types of plants? What are the challenges? and, What are our options?

- 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

In the palm oil industry, open ponding, aerobic and anaerobic digestion, physicochemical treatment and membrane filtration are generally applied as conventional treatments of palm oil mill effluent (POME). In this study, a sand filtration-dielectric barrier discharge (DBD) system was investigated as an alternative process for treating POME. This system can reduce land USAge, processing time and costs compared to conventional systems. The removal efficiency of chemical oxygen demand (COD), biological oxygen demand (BOD5), and oil-grease in relation to the applied voltage were studied. Furthermore, the pH and temperature profiles were investigated. The obtained results indicate that the removal efficiency of COD, BOD5, and oil-grease increased with an increase of the applied voltage. The electrical energy consumption needed is about 10.56 kWh/L of POME.

Enhanced crop growth and yield are the recurring concerns in agricultural field, considering the soaring world population and climate change. Abiotic stresses are one of the major limiting factors for constraining crop production, for several economically important horticultural crops, and contribute to almost 70% of yield gap. Salt stress is one of these unsought abiotic stresses that has become a consistent problem in agriculture over the past few years. Salinity further induces ionic, osmotic, and oxidative stress that result in various metabolic perturbations (including the generation of reactive oxygen, carbonyl, and nitrogen species), reduction in water potential (%w), distorted membrane potential, membrane injury, altered rates of photosynthesis, leaf senescence, and reduced nitrogen assimilation, among others); thereby provoking a drastic reduction in crop growth and yield. One of the strategies to mitigate salt stress is the use of natural plant extracts (PEs) instead of chemical fertilizers, thus limiting water, soil, and environmental pollution. PEs mainly consist of seeds, roots, shoots, fruits, flowers, and leaves concentrates employed either individually or in mixtures. Since PEs are usually rich in bioactive compounds (e.g., carotenoids, flavonoids, phenolics, etc.), therefore they are effective in regulating redox metabolism, thereby promoting plant growth and yield. However, various factors like plant growth stage, doses applied, application method, soil, and environmental conditions may greatly influence their impact on plants. PEs have been reported to enhance salt tolerance in plants primarily through modulation of signaling signatures and pathways (e.g., NaC, ANNA4, GIPC, SOS3, and SCaBP8 Ca2C sensors, etc.), and regulation of redox machinery [e.g., superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX), non-specific peroxidase (POX), glutathione peroxidase (GPX), peroxiredoxin (Prx), ascorbic acid (AsA), glutathione (GSH), a-tocopherol, etc.]. The current study highlights the role of PEs in terms of their sources, methods of preparation, and mode of action with subsequent physiological changes induced in plants against salinity. However, an explicit mode of action of PEs remains nebulous, which might be explicated utilizing transcriptomics, proteomics, metabolomics, and bioinformatics approaches. Being ecological and economical, PEs might pave the way for ensuring the food security in this challenging era of climate change. European Union's Horizon 2020 Project H2020-MSCA-RISE-2019 872181 European Union's Horizon 2020 Project H2020-MSCA-RISE-2020 101007702 FEDER (Fondo Europeo de Desarrollo Regional)- Junta de Andalucia 2018 P18-H0-4700

Resumo: O biodiesel e um combustível biodegradável, renovável e com menor emissão de gases poluentes do que o petrodiesel. Ele e composto por ésteres alquilícos de ácidos graxos obtidos pela transesterificação de óleos ou gorduras com um álcool de cadeia curta como o metanol ou o etanol. Os ésteres etílicos resultantes da transesterificação com o etanol ainda são pouco caracterizados. Dados de suas propriedades termofísicas e de equilíbrio de fases; que são muito importantes para o projeto, modelagem, simulação e otimização do processo de produção do biodiesel, são escassos na literatura. Neste trabalho determinaram-se dados de pressão de vapor dos ésteres laurato de etila, miristato de etila, palmitato de etila, estearato de etila, oleato de etila e linoleato de etila, e dados de equilíbrio líquido-vapor dos sistemas palmitato de etila + estearato de etila a 40 mmHg, palmitato de etila + oleato de etila a 40 e 70 mmHg e palmitato de etila + linoleato de etila a 70 mmHg. Para a determinação experimental propôs-se a utilização de uma técnica não convencional: a calorimetria exploratória diferencial ("Differential Scanning Calorimetry" - DSC). Nas analises foram utilizadas de 2-5 mg de amostra a uma taxa de aquecimento de 25 oC/min. As amostras foram colocadas em cadinhos herméticos de alumínio com um pequeno orifício na tampa ("pinhole") de 0,25 mm de diâmetro, para garantir a pressão interna constante. Para a determinação de dados de pressão de vapor, o DSC revelou-se ser uma técnica adequada e suas principais vantagens em relação as técnicas convencionais são: utilização de pequena quantidade de amostra e menor tempo de analise. Os dados de equilíbrio líquido-vapor medidos pelo DSC foram satisfatórios. Esta técnica mostrou-se restrita, não sendo adequada para a determinação do equilíbrio liquidovapor de sistemas cujos componentes apresentam grande diferença de volatilidade Abstract: Biodiesel is a biodegradable, renewable fuel with lower greenhouse gas emissions. It consists of the alkyl esters of fatty acids, obtained by the transesterification of fats and oils with a short chain alcohol such as methanol or ethanol. Ethyl esters resulting from transesterification with ethanol are poorly characterized. The thermophysical properties and phase equilibrium data involving the fatty acid ethyl esters are very important in the design, modeling, simulation, and the optimization of the production of biodiesel, are scarce in the literature. In this work was determined vapor pressure data of the esters ethyl laurate, ethyl myristate, ethyl palmitate, ethyl stearate, ethyl oleate and ethyl linoleate; and vapor-liquid equilibrium data of systems ethyl pamitate + ethyl stearate at 40 mmHg, ethyl palmitate + ethyl oleate at 40 and 70 mmHg and ethyl palmitate + ethyl linoleate ant 70 mmHg. For the experimental determination proposed the use of a non-conventional technique: differential scanning calorimetry (DSC). Samples of 2 to 5 mg were used in the analysis, with heating rate of 25 ?C/min. The samples were placed in hermetic aluminum crucibles with a small hole in the lid ("pinhole") of 0.25 mm diameter, which maintain a constant internal pressure. The technique of differential scanning calorimetry was shown to be appropriate to determining the vapor pressure of ethyl esters. This technique showed advantages over conventional techniques: the use of a small sample size and shorter analysis time. The vapor-liquid equilibrium data measured by DSC were satisfactory. This technique proved to be restricted and it is not suitable for determining the vapor-liquid equilibrium data of systems whose components have large difference in volatility Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Química Desenvolvimento de Processos Químicos Orientador: Maria Alvina Krähenbühl Doutor em Engenharia Química Doutorado

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%.