Yenilenebilir Enerjilerde Son Gelişmeler ve Çevre ve Ekonomi Üzerindeki Etkileri:Derleme Makale

Yıl 2021, Cilt: 8 Sayı: 2, 909 - 930, 31.05.2021

Muhammed Kanca Ibrahim Nazem Qader Mohammed Qadır Mediha Kök

https://doi.org/10.31202/ecjse.892712

Cited By: 1

Öz

Tüm dünyada artan nüfus ve genişleyen endüstriler, enerji ihtiyacının artmasına yol açtı. Günümüzde enerjilerin çoğu fosil yakıtlar tarafından üretildiğinden, CO2 gibi sera gazlarının oranı son derece artarak çevreyi ve diğer sektörleri etkiledi. Bu çalışmada, dünyada ve Türkiye'de kullanılan yenilenebilir enerjiler anlatılmıştır. Ayrıca, farklı araştırmacılar tarafından kapsanan farklı çalışma alanları vurgulanmıştır. Bununla birlikte, yenilenebilir enerjilerden yararlanılarak elde edilebilecek fırsat ve buna karşılık gelen avantajlar da belirlendi. Sonuç olarak, kalkınma konusunda iyi bir ilerleme kaydedilmiştir ve bu alanda, özellikle hükümetler, uluslararası kuruluşlar ve çok gelişmiş ve büyük özel şirketler tarafından yatırımlar yapılmıştır.

Anahtar Kelimeler

Yenilenebilir enerjiler, Ekonomi, Verimlilik

Recent Improvements in Renewable Energies and their effects on the Environment and the Economy: Review Article

Öz

The increasing populations and expanding industries all over the world led to enhance the need for energy. Since most of the nowadays energies are generated by fossil fuels, so the ratio of greenhouse gases like CO2 extremely increased that impacted the environment and other sectors. In this study, the renewable energies used globally and in Turkey have been described. Also, the different fields of studies, which covered by different researchers have been highlighted. Besides, the opportunity and the corresponding advantages that can be achieved by harnessing renewable energies have been determined. Consequently, there is good progress in development, and investments have been made in this area, especially by governments, international organizations, and highly advanced and large private companies.

Anahtar Kelimeler

Renewable energies, Economy, Efficiency

Kaynakça

• [1]. Dogaru L., "The Main Goals of the Fourth Industrial Revolution. Renewable Energy Perspectives", Procedia Manufacturing, 2020;46:397-401.
• [2]. Sotoca A., "The NOW dilemma in Energy. The possibilities for Architecture and Urbanism", Energy Procedia, 2017;115:1-5.
• [3]. Nykvist B. and Nilsson M., "Rapidly falling costs of battery packs for electric vehicles", Nature Climate Change, 2015;5(4):329-332.
• [4]. Zu C.-X. and Li H., "Thermodynamic analysis on energy densities of batteries", Energy & Environmental Science, 2011;4(8):2614-2624.
• [5]. Deyette J. and Clemmer S. L., "Increasing the Texas renewable energy standard: Economic and employment benefits". Union of Concerned Scientists; 2005.
• [6]. Le Quéré C., Jackson R. B., Jones M. W., Smith A. J. P., Abernethy S., Andrew R. M., De-Gol A. J., Willis D. R., Shan Y., Canadell J. G., Friedlingstein P., Creutzig F. and Peters G. P., "Temporary reduction in daily global CO2 emissions during the COVID-19 forced confinement", Nature Climate Change, 2020;10(7):647-653.
• [7]. BAHÇECİ S. and DALDABAN F., "Economic Analysis of Demand Side Management with Residential PV System and Energy Storage System", El-Cezerî Journal of Science and Engineering, 2020;7(1):67-78.
• [8]. KIRBAŞ İ. and ÇİFCİ A., "Feasibility Study of a Solar Power Plant Installation: A Case Study of Lake Burdur, Turkey", El-Cezerî Journal of Science and Engineering;6(3):830-835.
• [9]. Fuat T. and SHOJAEI S., "Past to Present: Solar Chimney Power Technologies", El-Cezerî Journal of Science and Engineering, 2019;6(1):220-235.
• [10]. AKKAŞ Ö. P. and Ertugrul C., "Optimal Operation of a Virtual Power Plant in a Day Ahead Market Considering Uncertainties of Renewable Generation and Risk Evaluation", El-Cezerî Journal of Science and Engineering, 2020;7(2):448-460.
• [11]. BP B. P., "BP statistical review of world energy", BP, London, 2015.
• [12]. BP B. P., "BP statistical review of world energy", BP, London, 2014.
• [13]. Atilgan İ., "An Outlook to Turkish Energy Potential", Journal of the Faculty of Engineering and Architecture of Gazi University, 2000;15(1):31-47.
• [14]. Bozkurt S. and Tür R., "Dünyada ve Türkiyede Hidroelektrik Enerji, Gelişimi ve Genel Değerlendirme", Su Yapıları Sempozyumu Kitabı. Antalya, 2015:322-330.
• [15]. Gadonneix P., Sambo A., Nadeau M., Statham B., Kim Y., Birnbaum L., Vargas Lleras J., Cho H., Ward G. and Arup Roy Choudhury A., "World energy resources 2013 survey", World Energy Council: London, UK, 2013.
• [16]. YILMAZ M., "Türkiye’nin enerji potansiyeli ve yenilenebilir enerji kaynaklarının elektrik enerjisi üretimi açısından önemi", Ankara Üniversitesi Çevrebilimleri Dergisi, 2012;4(2):33-54.
• [17]. Kaplan Y. A., "Overview of wind energy in the world and assessment of current wind energy policies in Turkey", Renewable and Sustainable Energy Reviews, 2015;43:562-568.
• [18]. Koç E. and Şenel M. C., "Dünyada ve Türkiye’de enerji durumu-genel değerlendirme", Mühendis ve Makina, 2013;54(639):32-44.
• [19]. Varınca K. B. and Gönüllü M. T., "Türkiye’de güneş enerjisi potansiyeli ve bu potansiyelin kullanım derecesi, yöntemi ve yaygınlığı üzerine bir araştırma", Ulusal Güneş ve Hidrojen Enerjisi Kongresi, 2006:21-23.
• [20]. Kumbur H., Özer Z., Özsoy H. D. and Avcı E. D., "Türkiye’de geleneksel ve yenilenebilir enerji kaynaklarının potansiyeli ve çevresel etkilerinin karşılaştırılması", Yeksem 2005, III. Yenilenebilir Enerji Kaynakları Sempozyumu ve Sergisi, 2005:19-21.
• [21]. Jeffrey H., Jay B. and Winskel M., "Accelerating the development of marine energy: Exploring the prospects, benefits and challenges", Technological Forecasting and Social Change, 2013;80(7):1306-1316.
• [22]. Hannan M. A., Lipu M. S. H., Ker P. J., Begum R. A., Agelidis V. G. and Blaabjerg F., "Power electronics contribution to renewable energy conversion addressing emission reduction: Applications, issues, and recommendations", Applied Energy, 2019;251:113404.
• [23]. Kaur H. and Kaur I., "Optimization and Control of Hybrid Renewable Energy Systems: A Review", Cognitive Informatics and Soft Computing, 2020:483-500.
• [24]. Yuan B.-Z. and Sun J., "Bibliometric and mapping of top papers in the subject category of green and sustainable science and technology based on ESI", COLLNET Journal of Scientometrics and Information Management, 2019;13(2):269-289.
• [25]. Li N., Xiang F. and Fratalocchi A., "Silicon‐Based Photocatalysis for Green Chemical Fuels and Carbon Negative Technologies", Advanced Sustainable Systems, 2021:2000242.
• [26]. Li X., Wen J., Low J., Fang Y. and Yu J., "Design and fabrication of semiconductor photocatalyst for photocatalytic reduction of CO2 to solar fuel", Science China Materials, 2014;57(1):70-100.
• [27]. Didenko N. and Romashkina E., editors. Assessment of the Influence of the Extraction of Energy Resources on the Environment. IOP conference series: earth and environmental science; 2018: IOP Publishing.
• [28]. Zhenghu D., Honglang X., Zhibao D., Xingdong H. and Gang W., "Estimate of total CO2 output from desertified sandy land in China", Atmospheric Environment, 2001;35(34):5915-5921.
• [29]. Burrell A. L., Evans J. P. and De Kauwe M. G., "Anthropogenic climate change has driven over 5 million km2 of drylands towards desertification", Nature Communications, 2020;11(1):3853.
• [30]. Rossi F., Olguín E. J., Diels L. and De Philippis R., "Microbial fixation of CO2 in water bodies and in drylands to combat climate change, soil loss and desertification", New Biotechnology, 2015;32(1):109-120.
• [31]. Peel M. C., Finlayson B. L. and McMahon T. A., "Updated world map of the Köppen-Geiger climate classification", Hydrol. Earth Syst. Sci., 2007;11(5):1633-1644.
• [32]. Heshmati A., Abolhosseini S. and Altmann J., "The development of renewable energy sources and its significance for the environment". Springer; 2015.
• [33]. Bose B. K., "Global energy scenario and impact of power electronics in 21st century", IEEE Transactions on Industrial Electronics, 2012;60(7):2638-2651.
• [34]. Ager J. W. and Lapkin A. A., "Chemical storage of renewable energy", Science, 2018;360(6390):707-708.
• [35]. Smejkal Q., Rodemerck U., Wagner E. and Baerns M., "Economic assessment of the hydrogenation of CO2 to liquid fuels and petrochemical feedstock", Chemie Ingenieur Technik, 2014;86(5):679-686.
• [36]. Qader I. N., Kök M., Dağdelen F. and Aydogdu Y., "A Review of Smart Materials: Researches and Applications", El-Cezerî Journal of Science and Engineering, 2019;6(3):755-788.
• [37]. Mohammed S. S., Mediha K., Qader I. N. and Dağdelen F., "The Developments of piezoelectric Materials and Shape Memory Alloys in Robotic Actuator Systems", Avrupa Bilim ve Teknoloji Dergisi, 2019(17):1014-1030.
• [38]. Nia E. M., Zawawi N. A. W. A. and Singh B. S. M., editors. A review of walking energy harvesting using piezoelectric materials. IOP Conference Series: Materials Science and Engineering; 2017: IOP Publishing.
• [39]. Qader I. N., Öner E., Kok M., Mohammed S. S., Dağdelen F., Kanca M. S. and Aydoğdu Y., "Mechanical and Thermal Behavior of Cu84−xAl13Ni3Hfx Shape Memory Alloys", Iranian Journal of Science and Technology, Transactions A: Science, 2020.
• [40]. Dagdelen F., Aldalawi M. A. K., Kok M. and Qader I. N., "Influence of Ni addition and heat treatment on phase transformation temperatures and microstructures of a ternary CuAlCr alloy", The European Physical Journal Plus, 2019;134(2):66.
• [41]. Ercan E., Dagdelen F. and Qader I. N., "Effect of tantalum contents on transformation temperatures, thermal behaviors and microstructure of CuAlTa HTSMAs", Journal of Thermal Analysis and Calorimetry, 2020;139(1):29-36.
• [42]. Kök M., Qader I. N., Mohammed S. S., Öner E., Dağdelen F. and Aydogdu Y., "Thermal stability and some thermodynamics analysis of heat treated quaternary CuAlNiTa shape memory alloy", Materials Research Express, 2019;7(1):015702.
• [43]. Mohammed S. S., Kok M., Qader I. N., Kanca M. S., Ercan E., Dağdelen F. and Aydoğdu Y., "Influence of Ta Additive into Cu84−xAl13Ni3 (wt%) Shape Memory Alloy Produced by Induction Melting", Iranian Journal of Science and Technology, Transactions A: Science, 2020;44(4):1167-1175.
• [44]. Qader I. N., Ercan E., Faraj B. A. M., Kok M., Dagdelen F. and Aydogdu Y., "The Influence of Time-Dependent Aging Process on the Thermodynamic Parameters and Microstructures of Quaternary Cu79–Al12–Ni4–Nb5 (wt%) Shape Memory Alloy", Iranian Journal of Science and Technology, Transactions A: Science, 2020;44(3):903-910.
• [45]. Qader I. N., Kök M. and Dağdelen F., "Effect of heat treatment on thermodynamics parameters, crystal and microstructure of (Cu-Al-Ni-Hf) shape memory alloy", Physica B: Condensed Matter, 2019;553:1-5.
• [46]. Balci E., Dagdelen F., Qader I. N. and Kok M., "Effects of substituting Nb with V on thermal analysis and biocompatibility assessment of quaternary NiTiNbV SMA", The European Physical Journal Plus, 2021;136(2):145.
• [47]. Buytoz S., Dagdelen F., Qader I. N., Kok M. and Tanyildizi B., "Microstructure Analysis and Thermal Characteristics of NiTiHf Shape Memory Alloy with Different Composition", Metals and Materials International, 2019.
• [48]. Acar E., Kok M. and Qader I. N., "Exploring surface oxidation behavior of NiTi–V alloys", The European Physical Journal Plus, 2020;135(1):58.
• [49]. Dagdelen F., Balci E., Qader I. N., Ozen E., Kok M., Kanca M. S., Abdullah S. S. and Mohammed S. S., "Influence of the Nb Content on the Microstructure and Phase Transformation Properties of NiTiNb Shape Memory Alloys", JOM, 2020;72(4):1664-1672.
• [50]. Dagdelen F., Kok M. and Qader I. N., "Effects of Ta Content on Thermodynamic Properties and Transformation Temperatures of Shape Memory NiTi Alloy", Metals and Materials International, 2019;25(6):1420-1427.
• [51]. Kök M., Al-Jaf A. O. A., Çirak Z. D., Qader I. N. and Özen E., "Effects of heat treatment temperatures on phase transformation, thermodynamical parameters, crystal microstructure, and electrical resistivity of NiTiV shape memory alloy", Journal of Thermal Analysis and Calorimetry, 2020;139(6):3405-3413.
• [52]. Qader I. N., Kok M. and Cirak Z. D., "The effects of substituting Sn for Ni on the thermal and some other characteristics of NiTiSn shape memory alloys", Journal of Thermal Analysis and Calorimetry, 2020.
• [53]. Kök M., Zardawi H. S. A., Qader I. N. and Sait Kanca M., "The effects of cobalt elements addition on Ti2Ni phases, thermodynamics parameters, crystal structure and transformation temperature of NiTi shape memory alloys", The European Physical Journal Plus, 2019;134(5):197.
• [54]. Tatar C., Acar R. and Qader I. N., "Investigation of thermodynamic and microstructural characteristics of NiTiCu shape memory alloys produced by arc-melting method", The European Physical Journal Plus, 2020;135(3):311.
• [55]. Li K., Dong Z., Liu Y. and Zhang L., "A newly developed Fe-based shape memory alloy suitable for smart civil engineering", Smart Materials and Structures, 2013;22(4):045002.
• [56]. Vollmer M., Arold T., Kriegel M. J., Klemm V., Degener S., Freudenberger J. and Niendorf T., "Promoting abnormal grain growth in Fe-based shape memory alloys through compositional adjustments", Nature Communications, 2019;10(1):2337.
• [57]. Czerny M., Cios G., Maziarz W., Chumlyakov Y. and Chulist R., "Studies on the Two-Step Aging Process of Fe-Based Shape Memory Single Crystals", Materials, 2020;13(7):1724.
• [58]. Riad A., Ben Zohra M., Mansouri M. and Alhamany A., "The shape memory alloy controlled by the sun’s radiation effect", Journal of Computational Methods in Sciences and Engineering, 2018;18(1):117-127.
• [59]. Vatansever D., Siores E. and Shah T., "Alternative resources for renewable energy: piezoelectric and photovoltaic smart structures", Global Warming-Impacts and Future Perspective, 2012;263.
• [60]. Prianka K. K., Hosain B. and Snigdha A., "Characterization and analysis of quantum-dot PV solar cells", Bangladesh: Northern University Bangladesh, 2016.
• [61]. Gude G., "Renewable energy powered desalination handbook: application and thermodynamics". Butterworth-Heinemann; 2018.
• [62]. Gude V. G., Nirmalakhandan N. and Deng S., "Renewable and sustainable approaches for desalination", Renewable and Sustainable Energy Reviews, 2010;14(9):2641-2654.
• [63]. Ertekin C., Evrendilek F. and Kulcu R., "Modeling spatio-temporal dynamics of optimum tilt angles for solar collectors in Turkey", Sensors, 2008;8(5):2913-2931.
• [64]. Yılmaz İ. H., "Residential use of solar water heating in Turkey: A novel thermo-economic optimization for energy savings, cost benefit and ecology", Journal of Cleaner Production, 2018;204:511-524.
• [65]. Jarahnejad M. and Zaidi A., Exploring the Potential of Renewable Energy in Telecommunications Industry 2018.
• [66]. Alkire R. C., Kolb D. M., Lipkowski J. and Ross P. N., "Photoelectrochemical materials and energy conversion processes". John Wiley & Sons; 2010.
• [67]. Datta M., "Electrochemical processing technologies in chip fabrication: challenges and opportunities", Electrochimica Acta, 2003;48(20):2975-2985.
• [68]. Drews T. O., Webb E. G., Ma D. L., Alameda J., Braatz R. D. and Alkire R. C., "Coupled mesoscale—continuum simulations of copper electrodeposition in a trench", AIChE Journal, 2004;50(1):226-240.
• [69]. Moffat T. P., Wheeler D., Edelstein M. D. and Josell D., "Superconformal film growth: Mechanism and quantification", IBM Journal of Research and Development, 2005;49(1):19-36.
• [70]. Ali J., Sohail A., Wang L., Rizwan Haider M., Mulk S. and Pan G., "Electro-microbiology as a promising approach towards renewable energy and environmental sustainability", Energies, 2018;11(7):1822.
• [71]. Retto J., "Sophia, first citizen robot of the world", ResearchGate, URL: https://www. researchgate. net, 2017.
• [72]. Kalogirou S., "Artificial intelligence in energy and renewable energy systems". Nova Publishers; 2007.
• [73]. Bilgili M., Bilirgen H., Ozbek A., Ekinci F. and Demirdelen T., "The role of hydropower installations for sustainable energy development in Turkey and the world", Renewable Energy, 2018;126:755-764.
• [74]. Ke L., Chang J. C. and Zheng Q., "Research on Measures of Civil Engineering Construction to Achieve the Landscape Green Energy Saving", Applied Mechanics and Materials, 2015;716-717:240-243.
• [75]. Charnes A., Cooper W., Lewin A. Y. and Seiford L. M., "Data Envelopment Analysis Theory, Methodology and Applications", Journal of the Operational Research Society, 1997;48(3):332-333.
• [76]. Liu L., Zhu B. and Wang G.-X., "Azoxystrobin-induced excessive reactive oxygen species (ROS) production and inhibition of photosynthesis in the unicellular green algae Chlorella vulgaris", Environmental Science and Pollution Research, 2015;22(10):7766-7775.
• [77]. Farhani S. and Shahbaz M., "What role of renewable and non-renewable electricity consumption and output is needed to initially mitigate CO2 emissions in MENA region?", Renewable and Sustainable Energy Reviews, 2014;40:80-90.
• [78]. Ocal O. and Aslan A., "Renewable energy consumption–economic growth nexus in Turkey", Renewable and Sustainable Energy Reviews, 2013;28:494-499.
• [79]. Mirza F. M. and Kanwal A., "Energy consumption, carbon emissions and economic growth in Pakistan: Dynamic causality analysis", Renewable and Sustainable Energy Reviews, 2017;72:1233-1240.
• [80]. Vickers N. J., "Animal Communication: When I’m Calling You, Will You Answer Too?", Current Biology, 2017;27(14):R713-R715.
• [81]. Amjid S. S., Bilal M. Q., Nazir M. S. and Hussain A., "Biogas, renewable energy resource for Pakistan", Renewable and Sustainable Energy Reviews, 2011;15(6):2833-2837.
• [82]. Adams S., Klobodu E. K. M. and Opoku E. E. O., "Energy consumption, political regime and economic growth in sub-Saharan Africa", Energy Policy, 2016;96:36-44.
• [83]. Adams S., Klobodu E. K. M. and Apio A., "Renewable and non-renewable energy, regime type and economic growth", Renewable Energy, 2018;125:755-767.
• [84]. Pachauri R. K., Allen M. R., Barros V. R., Broome J., Cramer W., Christ R., Church J. A., Clarke L., Dahe Q. and Dasgupta P., "Climate change 2014: synthesis report. Contribution of Working Groups I, II and III to the fifth assessment report of the Intergovernmental Panel on Climate Change". Ipcc; 2014.
• [85]. Grimaud A. and Rougé L., "Polluting non-renewable resources, innovation and growth: welfare and environmental policy", Resource and Energy Economics, 2005;27(2):109-129.
• [86]. Weinkle J., "The new political importance of the old hurricane risk: a contextual approach to understanding contemporary struggles with hurricane risk and insurance", Journal of Risk Research, 2019;22(3):320-333.
• [87]. Balsalobre-Lorente D., Shahbaz M., Roubaud D. and Farhani S., "How economic growth, renewable electricity and natural resources contribute to CO2 emissions?", Energy Policy, 2018;113:356-367.
• [88]. Zoundi Z., "CO2 emissions, renewable energy and the Environmental Kuznets Curve, a panel cointegration approach", Renewable and Sustainable Energy Reviews, 2017;72:1067-1075.
• [89]. Dogan E. and Ozturk I., "The influence of renewable and non-renewable energy consumption and real income on CO2 emissions in the USA: evidence from structural break tests", Environmental Science and Pollution Research, 2017;24(11):10846-10854.
• [90]. Ito K., "CO2 emissions, renewable and non-renewable energy consumption, and economic growth: Evidence from panel data for developing countries", International Economics, 2017;151:1-6.
• [91]. Sulaiman J., Azman A. and Saboori B., "The potential of renewable energy: using the environmental Kuznets curve model", American Journal of Environmental Sciences, 2013;9(2):103.
• [92]. Sharif A., Raza S. A., Ozturk I. and Afshan S., "The dynamic relationship of renewable and nonrenewable energy consumption with carbon emission: A global study with the application of heterogeneous panel estimations", Renewable Energy, 2019;133:685-691.
• [93]. Kahia M., Ben Jebli M. and Belloumi M., "Analysis of the impact of renewable energy consumption and economic growth on carbon dioxide emissions in 12 MENA countries", Clean Technologies and Environmental Policy, 2019;21(4):871-885.
• [94]. Bilgili F., Koçak E. and Bulut Ü., "The dynamic impact of renewable energy consumption on CO2 emissions: A revisited Environmental Kuznets Curve approach", Renewable and Sustainable Energy Reviews, 2016;54:838-845.
• [95]. Bélaïd F. and Youssef M., "Environmental degradation, renewable and non-renewable electricity consumption, and economic growth: Assessing the evidence from Algeria", Energy Policy, 2017;102:277-287.
• [96]. Bhattacharyya S. C., "Energy economics: concepts, issues, markets and governance". London: Springer Science & Business Media; 2011.
• [97]. Apergis N., Payne J. E., Menyah K. and Wolde-Rufael Y., "On the causal dynamics between emissions, nuclear energy, renewable energy, and economic growth", Ecological Economics, 2010;69(11):2255-2260.
• [98]. Bölük G. and Mert M., "Fossil & renewable energy consumption, GHGs (greenhouse gases) and economic growth: Evidence from a panel of EU (European Union) countries", Energy, 2014;74:439-446.
• [99]. Ben Jebli M. and Ben Youssef S., "The role of renewable energy and agriculture in reducing CO2 emissions: Evidence for North Africa countries", Ecological Indicators, 2017;74:295-301.
• [100]. Al-Mulali U., Saboori B. and Ozturk I., "Investigating the environmental Kuznets curve hypothesis in Vietnam", Energy Policy, 2015;76:123-131.