跳到主要內容

臺灣博碩士論文加值系統

(18.97.14.86) 您好!臺灣時間:2025/02/20 05:50
字體大小: 字級放大   字級縮小   預設字形  
回查詢結果 :::

詳目顯示

: 
twitterline
研究生:黃駿易
研究生(外文):HUANG, CHUN-YI
論文名稱:以主路徑分析法探討潔淨能源之學術發展
論文名稱(外文):Exploring the Academic Development of Clean Energy With Main Path Analysis
指導教授:陳凱瀛陳凱瀛引用關係
指導教授(外文):CHEN, KAI-YING
口試委員:林志平黃瀅瑛陳凱瀛
口試委員(外文):LIN, CHIH-PINGHUANG, YING-YINCHEN, KAI-YING
口試日期:2024-06-28
學位類別:碩士
校院名稱:國立臺北科技大學
系所名稱:工業工程與管理系
學門:工程學門
學類:工業工程學類
論文種類:學術論文
論文出版年:2024
畢業學年度:112
語文別:中文
論文頁數:78
中文關鍵詞:潔淨能源主路徑分析文獻探討
外文關鍵詞:Clean EnergyMain Path AnalysisCluster Analysis
相關次數:
  • 被引用被引用:0
  • 點閱點閱:70
  • 評分評分:
  • 下載下載:22
  • 收藏至我的研究室書目清單書目收藏:0
潔淨能源是當今全球永續發展的重要議題之一。隨著全球能源需求的急遽增長和氣候變化的嚴峻挑戰,潔淨能源的重要性日益凸顯。傳統的能源生產方式,例如燃煤和石油的使用,已經帶來了嚴重的環境問題,包括空氣和水污染,並導致溫室氣體的排放不斷上升,進一步加劇了全球暖化。在這樣的背景下,潔淨能源,如太陽能、風能、水力能等,成為實現永續發展目標的關鍵。本研究從學術界和專利界收集了有關潔淨能源的文獻,從web of science資料庫上蒐集了2563筆資料。首先我們在參考文獻上利用mainpath465和Pajek兩個軟體建立一個主要的脈絡,在此脈絡上進行主路徑分析,繪製出整體發展軌跡。主路徑分析法為潔淨能源的推動提供了清晰的框架,有助於政策制定者和相關利益相關者更好地理解各個因素之間的相互作用,從而制定更有效的政策和策略,推動潔淨能源的永續性發展。結果可以提供給產業、政府、學術界作為規劃未來潔淨能源發展的策略及方向,提供潔淨能源領域未來發展方向。
Clean energy is one of the crucial issues in today's global sustainable development. With the rapid growth in global energy demand and the severe challenges of climate change, the importance of clean energy is increasingly evident. Traditional methods of energy production, such as the use of coal and oil, have resulted in severe environmental problems, including air and water pollution, and have led to a continuous increase in greenhouse gas emissions, further exacerbating global warming. In this context, clean energy sources such as solar, wind, and hydropower have become key to achieving sustainable development goals.
This study collected literature on clean energy from both the academic and patent domains, with 2563 records gathered from the Web of Science database. Initially, we utilized two software tools, mainpath465 and Pajek, to establish a primary context within the referenced literature. Subsequently, we conducted main path analysis within this context to outline the overall development trajectory.
In summary, main path analysis provides a clear framework for advancing clean energy, aiding policymakers and stakeholders in better understanding the interactions among various factors. This, in turn, facilitates the formulation of more effective policies and strategies to promote the sustainable development of clean energy. The results can serve as valuable insights for industries, governments, and the academic community, guiding future planning for the strategic direction of clean energy development.

摘要 i
ABSTRACT ii
誌謝 iv
目錄 v
表目錄 vii
圖目錄 viii
第一章 緒論 1
1.1 研究背景 1
1.2 研究目的 4
1.3 研究架構 5
第二章 文獻探討 7
2.1潔淨能源類型 9
2.1.1太陽能 9
2.1.2風能 10
2.1.3水能 11
2.1.4地熱能 12
2.2 2050淨零排放 13
2.2.1能源轉型 14
2.3 SDGS 17
2.4 主路徑分析相關文獻探討 19
第三章 研究方法 22
3.1 研究流程 22
3.2資料來源 24
3.3關鍵詞檢索與資料蒐集 24
3.5 集群分析 29
3.6 g-index 和 h-index 30
3.7 文字雲 32
3.8 成長曲線分析 32
第四章 研究結果與分析 34
4.1資料統計與分析 35
4.1.1 期刊統計 35
4.1.2 作者統計 39
4.2潔淨能源之主路徑分析 40
4.3潔淨能源之集群分析 47
第五章 結論與建議 65
5.1 研究結論 65
5.2 研究建議 67
參考文獻 69

1.Energy Information Platform,取自:www.epa.gov/greenpower/what-green-power造訪日期:2023.12.25
2.https://www.iner.gov.tw/eip/msn.aspx?datatype=YW5hbHlzaXM=&id=MTg4
3.富蘭克林華美投信,取自:https://www.ftft.com.tw/areas/00899etf/index.html 造訪日期:2023.12.25
4.International Energy Agency . (2023). Germany's Energiewende: Transforming energy through innovation. Retrieved from https://www.iea.org/reports/germanys-energiewende-transforming-energy-through-innovation.
5.Global Wind Energy Council . (2022). Denmark's Wind Power Leadership. Retrieved from https://gwec.net/resources/publications/denmarks-wind-power-leadership.
6.California Energy Commission. (2022). California's Clean Energy Goals. Retrieved from https://www.energy.ca.gov/programs-and-topics/topics/clean-energy.
7.Ministry of Economic Affairs, Taiwan. (2016). Taiwan Renewable Energy Development Act. Retrieved from https://www.moea.gov.tw/MNS/english/news/News.aspx?kind=6&menu_id=176&news_id=52488.
8.Bureau of Energy, Ministry of Economic Affairs, Taiwan. (2023). Taiwan's Solar Energy Progress. Retrieved from https://www.moea.gov.tw/MNS/boe/news/News.aspx?kind=6&menu_id=176&news_id=89324.
9.Ministry of Economic Affairs, Taiwan. (2019). Taiwan's Offshore Wind Power Plan. Retrieved from https://www.moea.gov.tw/MNS/boe/news/News.aspx?kind=6&menu_id=176&news_id=74659.
10.Financial Supervisory Commission, Taiwan. (2022). Taiwan's Green Finance Initiatives. Retrieved from https://www.fsc.gov.tw/en/home.jsp?id=55&parentpath=0,2&mcustomize=multimessages_view.jsp&dataserno=202201060003&aplistdn=ou=data,ou=greenfinance,ou=multisite,ou=english,ou=ap_root,o=fsc,c=tw&dtable=News.
11.Ministry of Foreign Affairs, Taiwan. (2023). International Cooperation on Renewable Energy. Retrieved from https://www.mofa.gov.tw/en.
12.International Energy Agency . (2023). Solar Photovoltaic Technology. Retrieved from https://www.iea.org/reports/solar-photovoltaic-technology.
13.National Renewable Energy Laboratory . (2023). Emerging Solar Technologies. Retrieved from https://www.nrel.gov/docs/fy23osti/79034.pdf.
14.Energy Storage Association . (2023). Advances in Energy Storage Systems. Retrieved from https://energystorage.org/research/advances-in-energy-storage-systems-2023.
15.Solar Energy Industries Association . (2023). Community Solar and Distributed Generation. Retrieved from https://www.seia.org/research-resources/community-solar-and-distributed-generation-2023.
16.Global Wind Energy Council . (2022). Global Wind Report 2022. Retrieved from https://gwec.net/global-wind-report-2022.
17.International Energy Agency . (2023). Wind Energy Technology. Retrieved from https://www.iea.org/reports/wind-energy-technology.
18.National Renewable Energy Laboratory . (2023). Offshore Wind Market Report. Retrieved from https://www.nrel.gov/docs/fy23osti/80533.pdf.
19.Intergovernmental Panel on Climate Change . (2022). Climate Change 2022: Mitigation of Climate Change. Retrieved from https://www.ipcc.ch/report/ar6/wg3.
20.World Resources Institute. (2023). Renewable Energy: The Sustainable Choice. Retrieved from https://www.wri.org/research/renewable-energy-sustainable-choice-2023.
21.International Hydropower Association. (2022). Hydropower Status Report 2022. Retrieved from https://www.hydropower.org/statusreport.
22.World Energy Council. (2023). Tidal Energy: Current Status and Future Perspectives. Retrieved from https://www.worldenergy.org/publications/entry/tidal-energy-current-status-and-future-perspectives.
23.United Nations Environment Programme. (2022). Environmental and Social Impacts of Hydropower. Retrieved from https://www.unep.org/resources/report/environmental-and-social-impacts-hydropower.
24.European Commission. (2023). Sustainable Hydropower Development in the EU. Retrieved from https://ec.europa.eu/energy/topics/renewable-energy/hydropower_en.
25.International Hydropower Association. (2022). Hydropower Status Report 2022. Retrieved from https://www.hydropower.org/statusreport.
26.World Energy Council. (2023). Tidal Energy: Current Status and Future Perspectives. Retrieved from https://www.worldenergy.org/publications/entry/tidal-energy-current-status-and-future-perspectives.
27.U.S. Department of Energy. (2023). Geothermal Technologies Office. Retrieved from https://www.energy.gov/eere/geothermal/geothermal-technologies-office.
28.Journal of Renewable and Sustainable Energy. (2023). Chromium-Molybdenum Alloy Batteries for Geothermal Energy Storage. Retrieved from https://aip.scitation.org/doi/10.1063/1.51234.
29.World Bank. (2023). Geothermal Energy for Stable Power Supply. Retrieved from https://www.worldbank.org/en/topic/energy/publication/geothermal.
30.Intergovernmental Panel on Climate Change. (2022). Climate Change Mitigation: Geothermal Energy. Retrieved from https://www.ipcc.ch/report/ar6/wg3.
31.European Geothermal Energy Council. (2023). Integrating Geothermal Energy with Other Renewable Sources. Retrieved from https://www.egec.org/publications/integration-renewables.
32.United Nations Framework Convention on Climate Change. (2015). The Paris Agreement. Retrieved from https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement.
33.Intergovernmental Panel on Climate Change. (2018). Global Warming of 1.5°C: An IPCC Special Report. Retrieved from https://www.ipcc.ch/sr15/.
34.Rogelj, J., Shindell, D., Jiang, K., Fifita, S., Forster, P., Ginzburg, V., ... & Zickfeld, K. (2018). Mitigation Pathways Compatible with 1.5°C in the Context of Sustainable Development. In Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty. Retrieved from https://www.ipcc.ch/sr15/chapter/chapter-2/.
35.Rockström, J, Gaffney, O., Rogelj, J., Meinshausen, M., Nakicenovic, N., & Schellnhuber, H. J. (2017). A roadmap for rapid decarbonization. Science, 355(6331), 1269-1271. Retrieved from https://science.sciencemag.org/content/355/6331/1269.
36.European Commission. (2019). A European Green Deal. Retrieved from https://ec.europa.eu/info/strategy/priorities-2019-2024/european-green-deal_en.
37.ESG遠見永續共好,取自:https://esg.gvm.com.tw/article/3722 造訪日期:2023.12.25
38.ESG遠見永續共好,取自:https://esg.gvm.com.tw/article/3722造訪日期:2023.12.25
39.ESG遠見永續共好,取自:https://esg.gvm.com.tw/article/3722造訪日期:2023.12.25
40.東海大學-社會實踐資訊整合平台,取自:https://se.thu.edu.tw/SDGs.php 造訪日期:2023.12.25
41.綠色國際大學,取自:https://green.nttu.edu.tw/p/412-1048-10039.php?Lang=zh-tw造訪日期:2023.12.25
42.Norman P.HummonPatrickDereian, "Connectivity in a citation network: The development
of DNA theory", Social Networks, 1989, Vol.11, No.1, pp.39-63
43.Hummon N.P., Carley K., "Social networks as normal science", Social Networks, 1993,
Vol.15, No.1, pp.71-106
44.Liu J.S., Lu L.Y.Y., "An innovative approach to identify the knowledge diffusion path: The case of resource-based theory", Scientometrics, Vol.94, No.1, pp.225-246
45.https://clarivate.com/zh-hant/solutions/web-of-science/
46.Hummon, N.P.; Doreian, P. Connectivity in a citation network: The development of DNA theory. Soc. Netw. 1989, 11, 39–63
47.Vladimir Batagelj, "EFFICIENT ALGORITHMS FOR CITATION NETWORK
ANALYSIS", Computer Science, 2003, Vol.41, 897
48.Vladimir Batagelj, Andrej Mrvar, "Pajek—analysis and visualization of large networks",
Graph drawing software, 2004, pp.77-103
49.Girvan, M.; Newman, M.E. Community structure in social and biological networks. Proc. Natl. Acad. Sci. USA 2002, 99, 7821–7826.
50.Hirsch,J.E. An index to quantify an indivitual’s scientific research output. Proc.Natl.Acad.Sci. USA 2005,102,16569-16572
51.Egghe, L. “An improvement of the h-index: The g-index.” ISSI newsletter, vol.2,
no.1,2006, pp.8-9.
52.LEO EGGHE, "Theory and practise of the g-index", Scientometrics, 2006, Vol. 69, No. 1,pp.131-152
53.Wordle.Web of Science. http://www.wordle.net. 造訪日期:2023.12.25
54.Lee, J.C. and Geisser, s. (1975). Applications of growth curve prediction. Sankhya, A, 37, 239-256.
55.Hancock, L; Ralph, N ; Ali, SH. MAR 20 2018, Bolivia's lithium frontier: Can public private partnerships deliver a minerals boom for sustainable development, 551-560.
56.Shahbaz ; Balsalobre-Lorente ; Sinha, A (Sinha, Avik), APR 20 2019, Foreign direct Investment-CO2 emissions nexus in Middle East and North African countries: Importance of biomass energy consumption, 217,603-614.
57.Sinha, A ; Sengupta, T ; Alvarado, R , JAN 1 2020, Interplay between technological innovation and environmental quality: Formulating the SDG policies for next 11 economies, 242.
58.Zafar, Muhammad Wasif; Shahbaz, Muhammad ; Sinha, Avik ; Sengupta, Tuhin ; Qin, Quande, SEP 20 2020, How renewable energy consumption contribute to environmental quality? The role of education in OECD countries, 268.
59.Sinha, Avik ; Sengupta, Tuhin ; Saha, Tanaya, DEC 2020, Technology policy and environmental quality at crossroads: Designing SDG policies for select Asia Pacific countries, 161.
60.Chen, Maozhi ; Sinha, Avik ; Hu, Kexiang ; Shah, Muhammad Ibrahim, MAR 2021, Impact of technological innovation on energy efficiency in industry 4.0 era: Moderation of shadow economy in sustainable development, 164.
61.Balsalobre-Lorente, Daniel ; Sinha, Avik ; Driha, Oana M. ; Mubarik, Muhammad Shujaat, MAY 10 2021, Assessing the impacts of ageing and natural resource extraction on carbon emissions: A proposed policy framework for European economies, 296.
62.Cheng, Ya; Sinha, Avik ; Ghosh, Vinit ; Sengupta, Tuhin ; Luo, Huawei, SEP 15 2021, Carbon tax and energy innovation at crossroads of carbon neutrality: Designing a sustainable decarbonization policy, 294.
63.Anwar, Ahsan; Sinha, Avik ; Sharif, Arshian ; Siddique, Muhammad ; Irshad, Shoaib ; Anwar, Waseem; Malik, Summaira, MAY 2022, The nexus between urbanization, renewable energy consumption, financial development, and CO2 emissions: evidence from selected Asian countries, 24, 6556-6576.
64.Cai, Yanqi; Xu, Junwei ; Ahmad, Paiman ; Anwar, Ahsan, DEC 31 2022, What drives carbon emissions in the long-run? The role of renewable energy and agriculture in achieving the sustainable development goals, 35, 4603-4624.
65.Anwar, Ahsan ; Chaudhary, Amatul R. ; Malik, Summaira, FEB 2023, Modeling the macroeconomic determinants of environmental degradation in E-7 countries: The role of technological innovation and institutional quality, 23.
66.Liu, Haibing; Anwar, Ahsan ; Razzaq, Asif ; Yang, Lei, NOV 2022, The key role of renewable energy consumption, technological innovation and institutional quality in formulating the SDG policies for emerging economies: Evidence from quantile regression, 8, 11810-11824.
67.Liu, Yaofei ; Ali, Muhammad Sibt ; Cong, Phan The, APR 2023, Nexus between economic policy uncertainty and green growth in BRICS countries: evidence from panel quantile regression.
68.Jiang, Yongzhong ; Sharif, Arshian ; Anwar, Ahsan ; Cong, Phan The ; Lelchumanan, Bawani; Yen, Vu Thi ; Vinh, Nguyen Thi Thuy, NOV 2023, Does green growth in E-7 countries depend on economic policy uncertainty, institutional quality, and renewable energy? Evidence from quantile-based regression, 14.
69.Anwar, Ahsan; Huong, Nguyen Thi Thu; Sharif, Arshian ; Kilinc-Ata, Nurcan ; Citil, Mucahit ; Demirtas, Furkan, JAN 2024, Is a green world real or a dream? A look at green growth from green innovation and financial development: Evidence from fragile economies, 59, 98-112.
70.Durani, Farah; Bhowmik, Roni; Sharif, Arshian ; Anwar, Ahsan ; Syed, Qasim Raza, SEP 25 2023, Role of economic uncertainty, financial development, natural resources, technology, and renewable energy in the environmental Phillips curve framework, 420.
71.Wu, Yanan ; Anwar, Ahsan; Quynh, Nguyen Ngoc ; Abbas, Ali; Cong, Phan The, OCT 2023, Impact of economic policy uncertainty and renewable energy on environmental quality: testing the LCC hypothesis for fast growing economies.
72.Sarkodie, Samuel Asumadu, AUG 2018, The invisible hand and EKC hypothesis: what are the drivers of environmental degradation and pollution in Africa, 25, 21993-22022.
73.Sinha, Avik ; Sengupta, Tuhin, JAN 2019, Impact of energy mix on nitrous oxide emissions: an environmental Kuznets curve approach for APEC countries, 26, 2613-2622.
74.Sharma, Rajesh ; Sinha, Avik ; Kautish, Pradeep, FEB 20 2021, Does renewable energy consumption reduce ecological footprint? Evidence from eight developing countries of Asia, 285.
75.Sarkodie, Samuel Asumadu, AUG 2018, The invisible hand and EKC hypothesis: what are the drivers of environmental degradation and pollution in Africa, 25, 21993-22022.
76.Shahbaz, Muhammad; Balsalobre-Lorente, Daniel ; Sinha, Avik, APR 20 2019, Foreign direct Investment-CO2 emissions nexus in Middle East and North African countries: Importance of biomass energy consumption, 217,603-614.
77.Sinha, Avik ; Sengupta, Tuhin; Alvarado, Rafael, JAN 1 2020, Interplay between technological innovation and environmental quality: Formulating the SDG policies for next 11 economies, 242.
78.Zafar, Muhammad Wasif; Shahbaz, Muhammad ; Sinha, Avik ; Sengupta, Tuhin; Qin, Quande, SEP 20 2020, How renewable energy consumption contribute to environmental quality? The role of education in OECD countries, 268.
79.Sinha, Avik ; Sengupta, Tuhin ; Saha, Tanaya, DEC 2020, Technology policy and environmental quality at crossroads: Designing SDG policies for select Asia Pacific countries, 161.
80.Chen, Maozhi; Sinha, Avik ; Hu, Kexiang; Shah, Muhammad Ibrahim, MAR 2021, Impact of technological innovation on energy efficiency in industry 4.0 era: Moderation of shadow economy in sustainable development, 164.
81.Balsalobre-Lorente, Daniel ; Sinha, Avik ; Driha, Oana M ; Mubarik, Muhammad Shujaat, MAY 10 2021, Assessing the impacts of ageing and natural resource extraction on carbon emissions: A proposed policy framework for European economies, 296.
82.Cheng, Ya; Sinha, Avik ; Ghosh, Vinit ; Sengupta, Tuhin ; Luo, Huawei, SEP 15 2021, Carbon tax and energy innovation at crossroads of carbon neutrality: Designing a sustainable decarbonization policy, 294.
83.Anwar, Ahsan; Sinha, Avik ; Sharif, Arshian ; Siddique, Muhammad ; Irshad, Shoaib ; Anwar, Waseem; Malik, Summaira, MAY 2022, The nexus between urbanization, renewable energy consumption, financial development, and CO2 emissions: evidence from selected Asian countries, 24, 6556-6576.
84.Cai, Yanqi; Xu, Junwei ; Ahmad, Paiman ; Anwar, Ahsan, DEC 31 2022, What drives carbon emissions in the long-run? The role of renewable energy and agriculture in achieving the sustainable development goals, 35, 4603-4624.
85.Anwar, Ahsan ; Chaudhary, Amatul R. ; Malik, Summaira, FEB 2023, Modeling the macroeconomic determinants of environmental degradation in E-7 countries: The role of technological innovation and institutional quality, 23.
86.Liu, Haibing; Anwar, Ahsan ; Razzaq, Asif ; Yang, Lei, NOV 2022, The key role of renewable energy consumption, technological innovation and institutional quality in formulating the SDG policies for emerging economies: Evidence from quantile regression, 8, 11810-11824.
87.Liu, Yaofei; Ali, Muhammad Sibt e; Cong, Phan The, APR 2023, Nexus between economic policy uncertainty and green growth in BRICS countries: evidence from panel quantile regression.
88.Jiang, Yongzhong ; Sharif, Arshian ; Anwar, Ahsan ; Cong, Phan The ; Lelchumanan, Bawani ; Yen, Vu Thi ; Vinh, Nguyen Thi Thuy, NOV 2023, Does green growth in E-7 countries depend on economic policy uncertainty, institutional quality, and renewable energy? Evidence from quantile-based regression, 14.
89.Anwar, Ahsan ; Huong, Nguyen Thi Thu; Sharif, Arshian ; Kilinc-Ata, Nurcan ; Citil, Mucahit ; Demirtas, Furkan, JAN 2024, Is a green world real or a dream? A look at green growth from green innovation and financial development: Evidence from fragile economies, 59, 98-112.
90.Durani, Farah; Bhowmik, Roni; Sharif, Arshian ; Anwar, Ahsan ; Syed, Qasim Raza, SEP 25 2023, Role of economic uncertainty, financial development, natural resources, technology, and renewable energy in the environmental Phillips curve framework, 420.
91.Wu, Yanan ; Anwar, Ahsan; Quynh, Nguyen Ngoc ; Abbas, Ali; Cong, Phan The, OCT 2023, Impact of economic policy uncertainty and renewable energy on environmental quality: testing the LCC hypothesis for fast growing economies.
92.Haby, Michelle M. ; Chapman, Evelina ; Clark, Rachel ; Galvao, Luiz A. C, Energy interventions that facilitate sustainable development and impact health: an overview of systematic reviews, APR 2016, 39, 200-207.
93.Galvao, Luiz A. C ; Haby, Michelle M ; Chapman, Evelina ; Clark, Rachel ; Camara, Volney Magalhaes ; Luiz, Ronir Raggio ; Becerra-Posada, Francisco, MAR 2016, The new United Nations approach to sustainable development post-2015: Findings from four overviews of systematic reviews on interventions for sustainable development and health, 39, 157-165.
94.McCollum, David L. ; Echeverri, Luis Gomez ; Busch, Sebastian ; Pachauri, Shonali); Parkinson, Simon; Rogelj, Joeri ; Krey, Volker ; minx, Jan C.; Nilsson, Mans; Stevance, Anne-Sophie, MAR 2018, Connecting the sustainable development goals by their energy inter-linkages, 13.
95.Fader, Marianela ; Cranmer, Colleen ; Lawford, Richard ; Engel-Cox, Jill, NOV 12 2018, Toward an Understanding of Synergies and Trade-Offs Between Water, Energy, and Food SDG Targets, 6.
96.Ramos, de Miguel Ramos, Carlos ; Laurenti, Rafael, DEC 2020, Synergies and Trade-offs among Sustainable Development Goals: The Case of Spain, 12.
97.Sompolska-Rzechula, Agnieszka; Kurdys-Kujawska, Agnieszka, APR 2021, Towards Understanding Interactions between Sustainable Development Goals: The Role of Climate-Well-Being Linkages. Experiences of EU Countries, 14.
98.Zielinski, Mariusz ; Jonek-Kowalska, Izabela, JUN 2021, Does CSR Affect the Profitability and Valuation of Energy Companies? An Example from Poland, 14.
99.Lecka, Izabella ; Gudowski, Janusz ; Wolowiec, Tomasz, OCT 2022, CSR in Poland and the Implementation of Sustainable Development Goals in the Energy Sector during the COVID-19 Pandemic, 15.
100.Dmytrow, Krzysztof; Bieszk-Stolorz, Beata; Landmesser-Rusek, Joanna, OCT 2022, Sustainable Energy in European Countries: Analysis of Sustainable Development Goal 7 Using the Dynamic Time Warping Method, 15.
101.Kuc-Czarnecka, Marta; Markowicz, Iwona; Sompolska-Rzechula, Agnieszka, FEB 2023, SDGs implementation, their synergies, and trade-offs in EU countries - Sensitivity analysis-based approach, 146.
102.Mentis, D; Howells, M; Scholtz, E, AUG 2017, Lighting the World: the first application of an open source, spatial electrification tool (OnSSET) on Sub-Saharan Africa, 12.
103.Batchelor, Simon; Brown, Ed ; Scott, Nigel ; Leary, Jon, MAY 1 2019, Two Birds, One StoneReframing Cooking Energy Policies in Africa and Asia, 12.
104.Stritzke, Susann; Jain, Prem, JUL 2021, The Sustainability of Decentralised Renewable Energy Projects in Developing Countries: Learning Lessons from Zambia, 14.
105.Stritzke, Susann ; Jain, Prem, JUL 2021, The Sustainability of Decentralised Renewable Energy Projects in Developing Countries: Learning Lessons from Zambia, 14.
106.Falchetta, G; Michoud, B; Rother, M, AUG 2022, Harnessing finance for a new era of decentralised electricity access: A review of private investment patterns and emerging business models, 90.
107.Singh, S; Ru, J, MAR 2022, Accessibility, affordability, and efficiency of clean energy: a review and research agenda, 29, 18333-18347.
108.Gannan, Ismail ; Kubaji, Hussam ; Siwale, Workson ; Frodeson, Stefan ; Venkatesh, G., MAR 2023, Streamlined Social Footprint Analysis of the Nascent Bio-Pellet Sub-Sector in Zambia, 15.
109.Sayed, ET; Abdelkareem, MA; Olabi, AG, 2021, Progress in plant-based bioelectrochemical systems and their connection with sustainable development goals, 4, 169-183.
110.Olabi, AG; Obaideen, Khaled; Elsaid, Khaled ; Wilberforce, Tabbi ; Sayed, Enas Taha; Maghrabie, Hussein M.; Abdelkareem, Mohammad Ali, MA, JAN 2022, Assessment of the pre-combustion carbon capture contribution into sustainable development goals SDGs using novel indicators, 153.
111.Obaideen, Khaled ; Abdelkareem, Mohammad Ali; Wilberforce, Tabbi ; Elsaid, Khaled ; Sayed, Enas Taha ; Maghrabie, Hussein M.; Olabi, A. G., FEB 2022, Biogas role in achievement of the sustainable development goals: Evaluation, Challenges, and Guidelines, 131.
112.Obaideen, Khaled; Shehata, Nabila; Sayed, Enas Taha ; Abdelkareem, Mohammad Ali; Mahmoud, Mohamed S. ; Olabi, A. G., SEP 2022, The role of wastewater treatment in achieving sustainable development goals (SDGs) and sustainability guideline, 7.
113.Obaideen, Khaled ; Olabi, Abdul Ghani ; Al Swailmeen, Yaser; Shehata, Nabila; Abdelkareem, Mohammad Ali; Alami, Abdul Hai ; Rodriguez, Cristina ; Sayed, Enas Taha, JAN 2023, Solar Energy: Applications, Trends Analysis, Bibliometric Analysis and Research Contribution to Sustainable Development Goals (SDGs), 15.
114.Olabi, Abdul-Ghani ; Mahmoud, Montaser; Obaideen, Khaled; Sayed, Enas Taha ; Ramadan, Mohamad ; Abdelkareem, Mohammad Ali, JUN 1 2023, Ground source heat pumps: Recent progress, applications, challenges, barriers, and role in achieving sustainable development goals based on bibliometric analysis, 41.
115.Olabi, A. G. ; Abdelkareem, Mohammad Ali ; Mahmoud, Mohamed S.; Elsaid, Khaled; Obaideen, Khaled; Rezk, Hegazy ; Wilberforce, Tabbi ; Eisa, Tasnim ; Chae, Kyu-Jung ; Sayed, Enas Taha, SEP 2023, Green hydrogen: Pathways, roadmap, and role in achieving sustainable development goals, 177, 664-687.
116.Sekhar, Joseph S. ; Samuel, Melvin S.; Glivin, Godwin ; Le, TG; Mathimani, Thangavel, MAR 15 2024, Production and utilization of green ammonia for decarbonizing the energy sector with a discrete focus on Sustainable Development Goals and environmental impact and technical hurdles, 360.
117.Olabi, A. G. ; Abdelkareem, Mohammad Ali ; Mahmoud, Montaser ; Mahmoud, Mohamed S. ; Elsaid, Khaled; Obaideen, Khaled ; Rezk, Hegazy ; Eisa, Tasnim ; Chae, Kyu-Jung ; Sayed, Enas Taha, JAN 2 2024, Multiple-criteria decision-making for hydrogen production approaches based on economic, social, and environmental impacts, 52, 854-868.

QRCODE
 
 
 
 
 
                                                                                                                                                                                                                                                                                                                                                                                                               
第一頁 上一頁 下一頁 最後一頁 top
無相關期刊