Bioenergy as a prospective energy source in the future
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Abstract
The issues of global warming and greenhouse gasses have raised the concern of the people and led to integrate ambitious of using bioenergy in many countries. In this paper, the issues of conventional energy are stated, and the different types of conventional energy resources are discussed including coal, petroleum and natural gas. The process of pulverized coal combustion (PCC) to generate electricity is also studied and discussed in this paper to have a better understanding of the process and the emission of greenhouse gas released from the use of coal to generate conventional energy. The reason of soil contamination and air pollution caused by the refinery process of petroleum is also discussed in this paper and several study cases of the social economic impact caused by the production of natural gas in development countries. Furthermore, the used of bioenergy and different type of bioenergy resource are discussed including biogas, algae biofuel, and biodiesel. The process of algae cultivation for algae biofuel and the study of toxic waste algae strains that can give a negative impact to the environment is studied to avoid harmful substances released to the environment. The potential algae application in different fields is also included to show the benefit of algae biofuel which is flexible and able to contribute to the global economic growth. Lastly, the advantages of using bioenergy are discussed including the mitigation of greenhouse gas emission, improve social economic growth, renewable energy resources and prevent prescribed burning of the forest.
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Copyright (c) 2021 Tony Hadibarata, Nita Citrasari
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References
Abbasi, T., Tauseef, S. and Abbasi, S., 2012. Biogas and Biogas Energy: an introduction. Springer
Adeniyi, O. M., Azimov, U. and Burluka, A., 2018. Algae biofuel: Current status and future applications. Renew. Sust. Energ. Rev. 90, 316-335
Ahmad, F. B., Zhang, Z., Doherty, W. O. and O'Hara, I. M., 2019. The outlook of the production of advanced fuels and chemicals from integrated oil palm biomass biorefinery. Renew. Sust. Energ. Rev. 109, 386-411
Ahrens, T., Drescher-Hartung, S. and Anne, O., 2017. Sustainability of future bioenergy production. Waste Manag. 67, 1-2
Al‐Mofleh, A., Taib, S. and Salah, W. A., 2010. Malaysian energy demand and emissions from the transportation sector. Transport. 25, 448-453
Algieri, B., 2014. The influence of biofuels, economic and financial factors on daily returns of commodity futures prices. Energy Policy. 69, 227-247
Alsaleh, M., Abdul-Rahim, A. and Mohd-Shahwahid, H., 2017. Determinants of technical efficiency in the bioenergy industry in the EU28 region. Renew. Sust. Energ. Rev. 78, 1331-1349
Balat, M. and Balat, M., 2009. Political, economic and environmental impacts of biomass-based hydrogen. Int. J. Hydrog. Energy. 34, 3589-3603
Bilgen, S., 2014. Structure and environmental impact of global energy consumption. Renew. Sust. Energ. Rev. 38, 890-902
Brandt, A. R., 2011. Oil depletion and the energy efficiency of oil production: The case of California. Sustainability. 3, 1833-1854
Buchholz, T., Rametsteiner, E., Volk, T. A. and Luzadis, V. A., 2009. Multi criteria analysis for bioenergy systems assessments. Energy policy. 37, 484-495
Burchart-Korol, D., Korol, J. and Czaplicka-Kolarz, K., 2016. Life cycle assessment of heat production from underground coal gasification. Int J Life Cycle Assess. 21, 1391-1403
Chong, C., Ni, W., Ma, L., Liu, P. and Li, Z., 2015. The use of energy in Malaysia: Tracing energy flows from primary source to end use. Energies. 8, 2828-2866
Correa, S. M., Arbilla, G., Marques, M. R. and Oliveira, K. M., 2012. The impact of BTEX emissions from gas stations into the atmosphere. Atmos. Pollut. Res. 3, 163-169
da Silva César, A., Conejero, M. A., Ribeiro, E. C. B. and Batalha, M. O., 2019. Competitiveness analysis of “social soybeans” in biodiesel production in Brazil. Renew. Energy. 133, 1147-1157
Davison, J., 2005. Risk mitigation of genetically modified bacteria and plants designed for bioremediation. J. Ind. Microbiol. 32, 639-650
Dong, Y., Jiang, X., Liang, Z. and Yuan, J., 2018. Coal power flexibility, energy efficiency and pollutant emissions implications in China: A plant-level analysis based on case units. Resour Conserv Recycl. 134, 184-195
Dunn, M., McTaggart-Cowan, G. and Saunders, J., 2013. High efficiency and low emission natural gas engines for heavy duty vehicles. Elsevier
Escamilla-Alvarado, C., Poggi-Varaldo, H. M. and Ponce-Noyola, M. T., 2017. Bioenergy and bioproducts from municipal organic waste as alternative to landfilling: a comparative life cycle assessment with prospective application to Mexico. Environ. Sci. Pollut. Res. 24, 25602-25617
Faaij, A., Junginger, M. and Goh, C. S., 2014. A general introduction to international bioenergy trade. Springer
Gírio, F., 2019. Innovation on bioenergy. Elsevier
Hooftman, N., Oliveira, L., Messagie, M., Coosemans, T. and Van Mierlo, J., 2016. Environmental analysis of petrol, diesel and electric passenger cars in a Belgian urban setting. Energies. 9, 84
Hu, N., Liu, S., Gao, Y., Xu, J., Zhang, X., Zhang, Z. and Lee, X., 2018. Large methane emissions from natural gas vehicles in Chinese cities. Atmos. Environ. 187, 374-380
Johnson, M. B. and Wen, Z., 2009. Production of biodiesel fuel from the microalga Schizochytrium limacinum by direct transesterification of algal biomass. Energy & Fuels. 23, 5179-5183
Keller, V., Lyseng, B., English, J., Niet, T., Palmer-Wilson, K., Moazzen, I., Robertson, B., Wild, P. and Rowe, A., 2018. Coal-to-biomass retrofit in Alberta–value of forest residue bioenergy in the electricity system. Renew. Energy. 125, 373-383
Lee, D.-H., 2017. Econometric assessment of bioenergy development. Int. J. Hydrog. Energy. 42, 27701-27717
Lee, O. K. and Lee, E. Y., 2016. Sustainable production of bioethanol from renewable brown algae biomass. Biomass and Bioenergy. 92, 70-75
Liang, Q.-M., Fan, Y. and Wei, Y.-M., 2009. The effect of energy end-use efficiency improvement on China’s energy use and CO 2 emissions: a CGE model-based analysis. Energy Effic. 2, 243-262
Manaf, I. S. A., Embong, N. H., Khazaai, S. N. M., Rahim, M. H. A., Yusoff, M. M., Lee, K. T. and Maniam, G. P., 2019. A review for key challenges of the development of biodiesel industry. Energy Convers. Manag. 185, 508-517
Matzenberger, J., Kranzl, L., Tromborg, E., Junginger, M., Daioglou, V., Goh, C. S. and Keramidas, K., 2015. Future perspectives of international bioenergy trade. Renew. Sust. Energ. Rev. 43, 926-941
Moejes, F. W. and Moejes, K. B., 2017. Algae for Africa: microalgae as a source of food, feed and fuel in Kenya. African J Biotechnol. 16, 288-301
Mohr, L., Burg, V., Thees, O. and Trutnevyte, E., 2019. Spatial hot spots and clusters of bioenergy combined with socio-economic analysis in Switzerland. Renew. Energy. 140, 840-851
Muangjai, P., Wongsapai, W. and Damrongsak, D., 2017. Impact of Petroleum Products Subsidization to Energy Demand in Thailand. Energy Procedia. 138, 1011-1016
Nasir, I. M., Mohd Ghazi, T. I. and Omar, R., 2012. Anaerobic digestion technology in livestock manure treatment for biogas production: a review. Eng. Life Sci. 12, 258-269
Ning, J., Zhou, M., Pan, X., Li, C., Lv, N., Wang, T., Cai, G., Wang, R., Li, J. and Zhu, G., 2019. Simultaneous biogas and biogas slurry production from co-digestion of pig manure and corn straw: Performance optimization and microbial community shift. Bioresour. Technol. 282, 37-47
Paredes-Sánchez, J. P., López-Ochoa, L. M., López-González, L. M., Las-Heras-Casas, J. and Xiberta-Bernat, J., 2019. Evolution and perspectives of the bioenergy applications in Spain. J. Clean. Prod. 213, 553-568
Patowary, D., Ahmed, G. and Baruah, D., 2019. Biogas and Organic Fertilizer from Kitchen Waste Based Biogas Plant at Tezpur University, Assam. Springer
Pulighe, G., Bonati, G., Colangeli, M., Morese, M. M., Traverso, L., Lupia, F., Khawaja, C., Janssen, R. and Fava, F., 2019. Ongoing and emerging issues for sustainable bioenergy production on marginal lands in the Mediterranean regions. Renew. Sust. Energ. Rev. 103, 58-70
Rao, B., Ansari, F., Ankam, S., Kumar, A., Pandit, V. and Nema, P., 2005. Estimating fugitive emission budget of Volatile Organic Carbon (VOC) in a petroleum refinery. Bull Environ Contam Toxicol. 75, 127-134
Ratnasari, A., Syafiuddin, A., Boopathy, R., Malik, S., Aamer Mehmood, M., Amalia, R., Dwi Prastyo, D. and Syamimi Zaidi, N., 2022a. Advances in pretreatment technology for handling the palm oil mill effluent: Challenges and prospects. Bioresour. Technol. 344, 126239
Ratnasari, A., Syafiuddin, A., Zaidi, N. S., Hong Kueh, A. B., Hadibarata, T., Prastyo, D. D., Ravikumar, R. and Sathishkumar, P., 2022b. Bioremediation of micropollutants using living and non-living algae - Current perspectives and challenges. Env. Pol. 292, 118474
Ratnasari, A., Zaidi, N. S., Syafiuddin, A., Boopathy, R., Kueh, A. B. H., Amalia, R. and Prasetyo, D. D., 2021. Prospective biodegradation of organic and nitrogenous pollutants from palm oil mill effluent by acidophilic bacteria and archaea. Bioresour. Technol. 15, 100809
Röder, M. and Welfle, A., 2019. Bioenergy. Elsevier
Sánchez-Arreola, E., Bach, H. and Hernández, L. R., 2019. Biodiesel production from Cascabela ovata seed oil. Bioresour. Technol. 7, 100220
Scarlat, N. and Dallemand, J.-F., 2019. Chapter Ten - Future Role of Bioenergy. Academic Press
Scarlat, N., Dallemand, J.-F. and Fahl, F., 2018. Biogas: Developments and perspectives in Europe. Renew. Energy. 129, 457-472
Scholwin, F. and Nelles, M., 2013. Biogas biogas for Electricity Generation biogas for electricity generation, Hi-tech Applications biogas Hi-tech Applications. Renew. Energ. Syst. 161-169
Suganya, T., Varman, M., Masjuki, H. and Renganathan, S., 2016. Macroalgae and microalgae as a potential source for commercial applications along with biofuels production: a biorefinery approach. Renew. Sust. Energ. Rev. 55, 909-941
Thomson, E., 2003. The Chinese coal industry: An economic history. Routledge
Ulsrud, K., 2012. Bioenergy and sustainable adaptation to climate change in Africa. Springer
Wang, C., 2011. Sources of energy productivity growth and its distribution dynamics in China. Resour Energy Econ. 33, 279-292
Wang, C., Cao, X., Mao, J. and Qin, P., 2019. The changes in coal intensity of electricity generation in Chinese coal-fired power plants. Energy Econ. 80, 491-501
Wang, H., Xu, J., Sheng, L. and Liu, X., 2018. Effect of addition of biogas slurry for anaerobic fermentation of deer manure on biogas production. Energy. 165, 411-418
Whelan, S. and Wong, H., 2013. Dual-fuel heavy duty engines drive the dash for natural gas. Elsevier
Yilmaz, S., Toy, S., Yildiz, N. D. and Yilmaz, H., 2009. Human population growth and temperature increase along with the increase in urbanisation, motor vehicle numbers and green area amount in the sample of Erzurum city, Turkey. Environ. Monit. Assess. 148, 205-213
