Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler

Esra Özkan Aksu; Cevriye Gencer

doi:10.2339/politeknik.1653494

Araştırma Makalesi

Bibliometric Analysis for Offshore Wind Energy: Priority Research Areas and Emerging Trends

Yıl 2025, ERKEN GÖRÜNÜM, 1 - 1

Esra Özkan Aksu , Cevriye Gencer

https://doi.org/10.2339/politeknik.1653494

Öz

This study presents a bibliometric analysis to evaluate the current state of research in offshore wind energy, identify key research areas, and highlight emerging trends. The analysis is based on academic publications indexed in the Web of Science database from 2015 to 2025. The findings aim to identify the most influential publications, prominent researchers, and significant collaboration networks in the field. The results indicate that research in offshore wind energy has gained significant momentum in recent years, with a particular focus on power systems, sustainability, ocean dynamics, and modeling and simulation. The majority of studies have been published in academic journals, with the United States, China, the United Kingdom, and Germany contributing the most to the field. The predominant language of publications is English, and the most frequently used keywords include offshore wind energy, renewable energy, and wind energy. In this context, the findings emphasize the potential contribution of offshore wind energy research to policy development and sustainable energy strategies. This study serves as a valuable reference for researchers and policymakers by providing insights into innovative technologies and applications in the offshore wind energy sector.

Anahtar Kelimeler

Offshore wind energy, bibliometric analysis, research trends, renewable energy, scientific collaboration

Kaynakça

[1] Hsieh C-H., Lu L. Y., Lin C. H. and Liu J. S., ''Offshore Wind Energy Research Trajectory and Trends'', Portland International Conference on Management of Engineering and Technology, Portland, 1-5, (2018).
[2] Donthu N., Kumar S., Mukherjee D., Pandey N. and Lim W., ''How to conduct a bibliometric analysis: An overview and guidelines'', Journal of Business Research, 133: 285-296, (2021).
[3] Moral-Munoz J., Herrera-Viedma E., Santisteban-Espejo A. and Cobo M., ''Software tools for conducting bibliometric analysis in science: An up-to-date review'', El Profesional de la Información, 29(1), (2020).
[4] Gutiérrez-Salcedo M., Martínez M., Moral-Munoz J., Herrera-Viedma E. and Cobo M., ''Some bibliometric procedures for analyzing and evaluating research fields'', Applied Intelligence, 48: 1275-1287, (2017).
[5] Oliveira O., Da Silva F., Juliani F., Barbosa L. and Nunhes T., ''Bibliometric Method for Mapping the State-of-the-Art and Identifying Research Gaps and Trends in Literature: An Essential Instrument to Support the Development of Scientific Projects'', Scientometrics Recent Advances, IntechOpen, (2019).
[6] Lyu P., Liu X. and Yao T., ''A bibliometric analysis of literature on bibliometrics in recent half-century'', Journal of Information Science, 1-21, (2023).
[7] Veers P., Bottasso C., Manuel L., Naughton J., Pao L., Paquette J., Robertson A., Robinson M., Ananthan S., Barlas T., Bianchini A., Bredmose H., Horcas S., Keller J., Madsen H., Manwell J., Moriarty P., Nolet S. and Rinker J., ''Grand challenges in the design, manufacture, and operation of future wind turbine systems'', Wind Energy Science, 8(7): 1071-1131, (2023).
[8] Aksu E. Ö. and Gencer C. T., ''GIS-based optimum location selection for offshore wind energy: A case study for Turkey'', Ocean Engineering, 320: 120292, (2025).
[9] Afridi S., Koondhar M., Jamali M., Alaas Z., Alsharif M., Kim M., Mahariq I., Touti E., Aoudia M. and Ahmed M., ''Winds of Progress: An In-Depth Exploration of Offshore, Floating, and Onshore Wind Turbines as Cornerstones for Sustainable Energy Generation and Environmental Stewardship'', IEEE Access, 12: 66147-66166, (2024).
[10] Velenturf A., ''A Framework and Baseline for the Integration of a Sustainable Circular Economy in Offshore Wind'', Energies, 14(17): 5540, (2021).
[11] Barooni M., Ashuri T., Sogut D., Wood S. and Taleghani S., ''Floating Offshore Wind Turbines: Current Status and Future Prospects'', Energies, 16(1): 2, (2022).
[12] Huang Y., Gan X. and Chiueh P., ''Life cycle assessment and net energy analysis of offshore wind power systems'', Renewable Energy, 102: 98-106, (2017).
[13] Kaldellis J. and Apostolou D., ''Life cycle energy and carbon footprint of offshore wind energy. Comparison with onshore counterpart'', Renewable Energy, 108: 72-84, (2017).
[14] Gupta R. K., ''Advancements in Offshore Wind Energy Technology: Challenges and Opportunities for Sustainable Power Generation'', Indian Journal of Renewable Energy, 1(1): 1-6, (2024).
[15] Li J., Wang G., Li Z., Yang S., Chong W. and Xiang X., ''A review on development of offshore wind energy conversion system'', International Journal of Energy Research, 44: 9283-9297, (2020).
[16] Malhotra S., ''Design and Construction Considerations for Offshore Wind Turbine Foundations'', 26th International Conference on Offshore Mechanics and Arctic Engineering, San Diego, California, June 10-15, (2007).
[17] Kaldellis J., Apostolou D., Kapsali M. and Kondili E., ''Environmental and social footprint of offshore wind energy. Comparison with onshore counterpart'', Renewable Energy, 92: 543-556, (2016).
[18] Yang C., Jia J., He K., Xue L., Jiang C., Liu S., Zhao B., Wu M. and Cui H., ''Comprehensive Analysis and Evaluation of the Operation and Maintenance of Offshore Wind Power Systems: A Survey'', Energies, (2023).
[19] Shields M., Beiter P., Nunemaker J., Cooperman A. and Duffy P., ''Impacts of turbine and plant upsizing on the levelized cost of energy for offshore wind'', Applied Energy, 298: 117189, (2021).
[20] Mehta M., Zaaijer M. and Von Terzi D., ''Drivers for optimum sizing of wind turbines for offshore wind farms'', Wind Energy Science, 9(1): 141-163, (2024).
[21] Janocha M., Lee C., Wen X., Ong M., Raunholt L., Larsen Ø. and Søyland S., ''Exploring the Technical Boundaries in Upscaling Floating Offshore Wind Turbines'', International Conference on Offshore Mechanics and Arctic Engineering, Vol. 87851. American Society of Mechanical Engineers, (2024).
[22] Uzondu N. and Lele D., ''Comprehensive analysis of advancements in wind turbine design and offshore wind energy integration: Technological innovations, economic viability and environmental impacts'', International Journal of Applied Research in Social Sciences, 6(8), (2024).
[23] Bošnjaković M., Katinić M., Sánta R. and Marić D., ''Wind Turbine Technology Trends'', Applied Sciences, 12(17): 8653, (2022).
[24] Niu Y., Dwivedi A., Sathiaraj J., Lathi P. and Nagamune R., ''Floating Offshore Wind Farm Control via Turbine Repositioning: Unlocking the Potential Unique to Floating Offshore Wind'', IEEE Control Systems, 44: 106-129, (2024).
[25] Zhang Q., Zhang H., Yan Y., Yan J., He J., Li Z., Shang W. and Liang Y., ''Sustainable and clean oilfield development: How access to wind power can make offshore platforms more sustainable with production stability'', Journal of Cleaner Production, 294: 126225, (2021).
[26] Vargas A., Espinoza-Mina M., Alvarez D. and Espinosa J., ''Bibliometric Software: The Most Commonly Used in Research'', In ICAI Workshops, 47-65, (2022).
[27] Van Eck N. and Waltman L., ''Citation-based clustering of publications using CitNetExplorer and VOSviewer'', Scientometrics, 111: 1053-1070, (2017).
[28] Sajovic I. and Podgornik B., ''Bibliometric Analysis of Visualizations in Computer Graphics: A Study'', SAGE Open, 12, (2022).
[29] Ding X. and Yang Z., ''Knowledge mapping of platform research: a visual analysis using VOSviewer and CiteSpace'', Electronic Commerce Research, 1-23, (2020).
[30] Smyrnova-Trybulska E., Morze N., Kuzminska O. and Kommers P., ''Mapping and visualization: selected examples of international research networks'', Journal of Information, Communication and Ethics in Society, 16: 381-400, (2018).
[31] Van Eck N. and Waltman L., ''Software survey: VOSviewer, a computer program for bibliometric mapping'', Scientometrics, 84: 523-538, (2009).
[32] McAllister J., Lennertz L. and Mojica Z., ''Mapping A Discipline: A Guide to Using VOSviewer for Bibliometric and Visual Analysis'', Science & Technology Libraries, 41: 319-348, (2021).
[33] Rong J., ''Co-citation and Visualized Analysis of Literatures in Library and Information Science Based on Web of Science and VOSviewer'', Academic Journal of Humanities & Social Sciences, 7(8): 62-73, (2024).
[34] Borgohain D., Bhardwaj R. and Verma M., ''Computational Mapping of Indian Organic Chemistry Research: An Analysis with Data Mining Tools'', Journal of Scientometric Research, 13(1): 176-191, (2024).
[35] Tanwar M. and Verma H., ''Scientific Mapping of Chatbot Literature: A Bibliometric Analysis'', International Journal of Mathematical, Engineering and Management Sciences, 9(2): 323-340, (2024).
[36] Klarin A., ''How to conduct a bibliometric content analysis: Guidelines and contributions of content co‐occurrence or co‐word literature reviews'', International Journal of Consumer Studies, 48(2): e13031, (2024).
[37] Sheela S., Ali A., Tanaraj K. and Izani I., ''Navigating the Future: Blockchain’s Impact on Accounting and Auditing Practices'', Sustainability, 15(24): 16887, (2023).
[38] Fernandez-Rodriguez M. and Alvarez L., ''Microgels and Nanogels at Interfaces and Emulsions: Identifying Opportunities From a Bibliometric Analysis'', (2021).
[39] Bonilla-Chaves E. and Palos-Sánchez P., ''Exploring the Evolution of Human Resource Analytics: A Bibliometric Study'', Behavioral Sciences, 13(3): 244, (2023).
[40] Chen C., ''The centrality of pivotal points in the evolution of scientific networks'', Proceedings of the 10th International Conference on Intelligent User Interfaces, 98-105, (2005).
[41] Markscheffel B. and Schröter F., ''Comparison of two science mapping tools based on software technical evaluation and bibliometric case studies'', COLLNET Journal of Scientometrics and Information Management, 15: 365-396, (2021).
[42] Stojanović A., ''Knowledge mapping of research on Industry 4.0: A visual analysis using CiteSpace'', Serbian Journal of Management, 17(1): 125-143, (2022).
[43] Anish R. A., S. J., Jose J., P. N. and Joseph A., ''Navigating the Web of Influence: A Bibliometric Analysis of Social Media Addiction'', Cureus, 16(6), (2024).
[44] Chen C. and Song M., ''Science Mapping Tools and Applications'', Representing scientific knowledge: The role of uncertainty, 57-137, (2017).
[45] Barbu L., Mihaiu D., Serban R. and Opreana A., ''Knowledge Mapping of Optimal Taxation Studies: A Bibliometric Analysis and Network Visualization'', Sustainability, 14(2): 1043, (2022).
[46] Cui Y., Mou J. and Liu Y., ''Knowledge mapping of social commerce research: a visual analysis using CiteSpace'', Electronic Commerce Research, 18: 837-868, (2018).
[47] Cobo M., López-Herrera A., Herrera-Viedma E. and Herrera F., ''SciMAT: A new science mapping analysis software tool'', Journal of the Association for Information Science and Technology, 63: 1609-1630, (2012).
[48] Vasconcelos L., Sigahi T., De Souza Pinto J., Rampasso I. and Anholon R., ''Supply chain management maturity and business models: scientific mapping using SciMAT'', Benchmarking: An International Journal, 32(1): 26-51, (2023).
[49] Rincon-Patino J., Ramírez-González G. and Corrales J., ''Exploring machine learning: A bibliometric general approach using SciMAT'', F1000Research, 7: 1210, (2018).
[50] Morooka F., Manoel A., Sigahi T., De Souza Pinto J., Rampasso I. and Anholon R., ''Deep Learning and Autonomous Vehicles: Strategic Themes, Applications and Research Agenda Using SciMAT and Content-Centric Analysis, a Systematic Review'', Machine Learning and Knowledge Extraction, 5: 763-781, (2023).
[51] Ruiz-Rosero J., Ramírez-González G. and Viveros-Delgado J., ''Software survey: ScientoPy, a scientometric tool for topics trend analysis in scientific publications'', Scientometrics, 121: 1165-1188, (2019).
[52] Bador E., Abdel-Magid I., Ahmad S. and Akhter M., ''Bibliometric Analysis of Wastewater Literature Published in Web of Science 2019 to 2020'', Library Philosophy and Practice, 1-21, (2020).
[53] Ishak N. S., Roslan M. F. and Abdullah K. H., ''Bibliometric analysis of Malaysian authorship: Trends, patterns and prospects'', Asian Journal of Research in Education and Social Sciences, 5(2): 33-44, (2023).
[54] Barzehkar M., Parnell K., Soomere T., & Koivisto M. ''Offshore wind power plant site selection in the Baltic Sea'', Regional Studies in Marine Science, 73: 103469, (2024).
[55] Ren Z., Zhang S., Su Y., Yao Z., Huang R., & Wang P., ''Low-carbon policy simulation for offshore wind power development in China's net-zero power sector'', Energy Policy, 205: 114700, (2025).
[56] Barooni M, Ashuri T, Velioglu Sogut D, Wood S, Ghaderpour Taleghani S., ''Floating Offshore Wind Turbines: Current Status and Future Prospects'', Energies, 16(1): 2, (2023).
[57] Galparsoro I., Menchaca I., Garmendia J. M., Borja Á., Maldonado A. D., Iglesias G., & Bald J., ''Reviewing the ecological impacts of offshore wind farms'', npj Ocean Sustainabiltiy, 1: 1, (2022).
[58] Cutajar C, Sant T, Aquilina L, Buhagiar D, Baldacchino D., ''Subsea Long-Duration Energy Storage for Integration with Offshore Wind Farms'', Energies, 17(24): 6405, (2024).
[59] Rabanal A., Smith A. M., Ahaotu C. C., & Tedeschi E., ''Energy storage systems for services provision in offshore wind farms'', Renewable and Sustainable Energy Reviews, 200: 114573, (2024).
[60] Zhang H., Xiang W., & Wen J., ''Dual Grid-Forming Control With Energy Regulation Capability of MMC-HVDC System Integrating Offshore Wind Farms and Weak Grids'', IEEE Transactions on Power Systems, 39: 261-272, (2024).
[61] Hu H., Xue W., Jiang P., & Li, Y., ''Bibliometric analysis for ocean renewable energy: An comprehensive review for hotspots, frontiers, and emerging trends'', Renewable and Sustainable Energy Reviews, 167: 112739, (2022).
[62] Agyekum E. B., Khan T., Ampah J. D., Giri N. C., Mbasso W. F., & Kamel S., ''Review of the marine energy environment-a combination of traditional, bibliometric and PESTEL analysis'', Heliyon, 10(6), (2024).

Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler

Yıl 2025, ERKEN GÖRÜNÜM, 1 - 1

Esra Özkan Aksu , Cevriye Gencer

https://doi.org/10.2339/politeknik.1653494

Öz

Bu çalışma, deniz üzeri rüzgâr enerjisi alanında yürütülen araştırmaların mevcut durumunu değerlendirmek, öncelikli araştırma konularını ve gelişen eğilimleri ortaya koymak amacıyla bibliyometrik bir analiz sunmaktadır. Çalışma kapsamında, Web of Science veri tabanında 2015-2025 yılları arasında yayımlanmış akademik eserler incelenmiştir. Analiz bulguları, bu alandaki en etkili yayınları, öne çıkan araştırmacıları ve önemli iş birliği ağlarını belirlemeye yöneliktir. Sonuçlar, deniz üzeri rüzgâr enerjisi araştırmalarının son yıllarda önemli bir ivme kazandığını ve özellikle güç sistemleri, sürdürülebilirlik, okyanus dinamikleri ile modelleme ve simülasyon alanlarında yoğunlaştığını göstermektedir. Çalışmaların büyük çoğunluğunun akademik dergilerde yayımlandığı ve en fazla katkıyı Amerika Birleşik Devletleri, Çin, İngiltere ve Almanya’nın sağladığı tespit edilmiştir. Yayınların büyük bir kısmı İngilizce olup, en sık kullanılan anahtar kelimeler arasında offshore wind energy, renewable energy ve wind energy yer almaktadır. Bu bağlamda, elde edilen bulguların deniz üzeri rüzgâr enerjisi politikalarının şekillendirilmesine ve sürdürülebilir enerji stratejilerine katkı sağlayabileceği vurgulanmaktadır. Çalışma, sektördeki yenilikçi teknolojilerin ve uygulamaların gelişimini destekleyen değerli bir kaynak sunarak, araştırmacılar ve politika yapıcılar için önemli bir referans niteliği taşımaktadır.

Anahtar Kelimeler

Deniz üzeri rüzgâr enerjisi, bibliyometrik analiz, araştırma eğilimleri, yenilenebilir enerji, bilimsel iş birliği

Kaynakça

[1] Hsieh C-H., Lu L. Y., Lin C. H. and Liu J. S., ''Offshore Wind Energy Research Trajectory and Trends'', Portland International Conference on Management of Engineering and Technology, Portland, 1-5, (2018).
[2] Donthu N., Kumar S., Mukherjee D., Pandey N. and Lim W., ''How to conduct a bibliometric analysis: An overview and guidelines'', Journal of Business Research, 133: 285-296, (2021).
[3] Moral-Munoz J., Herrera-Viedma E., Santisteban-Espejo A. and Cobo M., ''Software tools for conducting bibliometric analysis in science: An up-to-date review'', El Profesional de la Información, 29(1), (2020).
[4] Gutiérrez-Salcedo M., Martínez M., Moral-Munoz J., Herrera-Viedma E. and Cobo M., ''Some bibliometric procedures for analyzing and evaluating research fields'', Applied Intelligence, 48: 1275-1287, (2017).
[5] Oliveira O., Da Silva F., Juliani F., Barbosa L. and Nunhes T., ''Bibliometric Method for Mapping the State-of-the-Art and Identifying Research Gaps and Trends in Literature: An Essential Instrument to Support the Development of Scientific Projects'', Scientometrics Recent Advances, IntechOpen, (2019).
[6] Lyu P., Liu X. and Yao T., ''A bibliometric analysis of literature on bibliometrics in recent half-century'', Journal of Information Science, 1-21, (2023).
[7] Veers P., Bottasso C., Manuel L., Naughton J., Pao L., Paquette J., Robertson A., Robinson M., Ananthan S., Barlas T., Bianchini A., Bredmose H., Horcas S., Keller J., Madsen H., Manwell J., Moriarty P., Nolet S. and Rinker J., ''Grand challenges in the design, manufacture, and operation of future wind turbine systems'', Wind Energy Science, 8(7): 1071-1131, (2023).
[8] Aksu E. Ö. and Gencer C. T., ''GIS-based optimum location selection for offshore wind energy: A case study for Turkey'', Ocean Engineering, 320: 120292, (2025).
[9] Afridi S., Koondhar M., Jamali M., Alaas Z., Alsharif M., Kim M., Mahariq I., Touti E., Aoudia M. and Ahmed M., ''Winds of Progress: An In-Depth Exploration of Offshore, Floating, and Onshore Wind Turbines as Cornerstones for Sustainable Energy Generation and Environmental Stewardship'', IEEE Access, 12: 66147-66166, (2024).
[10] Velenturf A., ''A Framework and Baseline for the Integration of a Sustainable Circular Economy in Offshore Wind'', Energies, 14(17): 5540, (2021).
[11] Barooni M., Ashuri T., Sogut D., Wood S. and Taleghani S., ''Floating Offshore Wind Turbines: Current Status and Future Prospects'', Energies, 16(1): 2, (2022).
[12] Huang Y., Gan X. and Chiueh P., ''Life cycle assessment and net energy analysis of offshore wind power systems'', Renewable Energy, 102: 98-106, (2017).
[13] Kaldellis J. and Apostolou D., ''Life cycle energy and carbon footprint of offshore wind energy. Comparison with onshore counterpart'', Renewable Energy, 108: 72-84, (2017).
[14] Gupta R. K., ''Advancements in Offshore Wind Energy Technology: Challenges and Opportunities for Sustainable Power Generation'', Indian Journal of Renewable Energy, 1(1): 1-6, (2024).
[15] Li J., Wang G., Li Z., Yang S., Chong W. and Xiang X., ''A review on development of offshore wind energy conversion system'', International Journal of Energy Research, 44: 9283-9297, (2020).
[16] Malhotra S., ''Design and Construction Considerations for Offshore Wind Turbine Foundations'', 26th International Conference on Offshore Mechanics and Arctic Engineering, San Diego, California, June 10-15, (2007).
[17] Kaldellis J., Apostolou D., Kapsali M. and Kondili E., ''Environmental and social footprint of offshore wind energy. Comparison with onshore counterpart'', Renewable Energy, 92: 543-556, (2016).
[18] Yang C., Jia J., He K., Xue L., Jiang C., Liu S., Zhao B., Wu M. and Cui H., ''Comprehensive Analysis and Evaluation of the Operation and Maintenance of Offshore Wind Power Systems: A Survey'', Energies, (2023).
[19] Shields M., Beiter P., Nunemaker J., Cooperman A. and Duffy P., ''Impacts of turbine and plant upsizing on the levelized cost of energy for offshore wind'', Applied Energy, 298: 117189, (2021).
[20] Mehta M., Zaaijer M. and Von Terzi D., ''Drivers for optimum sizing of wind turbines for offshore wind farms'', Wind Energy Science, 9(1): 141-163, (2024).
[21] Janocha M., Lee C., Wen X., Ong M., Raunholt L., Larsen Ø. and Søyland S., ''Exploring the Technical Boundaries in Upscaling Floating Offshore Wind Turbines'', International Conference on Offshore Mechanics and Arctic Engineering, Vol. 87851. American Society of Mechanical Engineers, (2024).
[22] Uzondu N. and Lele D., ''Comprehensive analysis of advancements in wind turbine design and offshore wind energy integration: Technological innovations, economic viability and environmental impacts'', International Journal of Applied Research in Social Sciences, 6(8), (2024).
[23] Bošnjaković M., Katinić M., Sánta R. and Marić D., ''Wind Turbine Technology Trends'', Applied Sciences, 12(17): 8653, (2022).
[24] Niu Y., Dwivedi A., Sathiaraj J., Lathi P. and Nagamune R., ''Floating Offshore Wind Farm Control via Turbine Repositioning: Unlocking the Potential Unique to Floating Offshore Wind'', IEEE Control Systems, 44: 106-129, (2024).
[25] Zhang Q., Zhang H., Yan Y., Yan J., He J., Li Z., Shang W. and Liang Y., ''Sustainable and clean oilfield development: How access to wind power can make offshore platforms more sustainable with production stability'', Journal of Cleaner Production, 294: 126225, (2021).
[26] Vargas A., Espinoza-Mina M., Alvarez D. and Espinosa J., ''Bibliometric Software: The Most Commonly Used in Research'', In ICAI Workshops, 47-65, (2022).
[27] Van Eck N. and Waltman L., ''Citation-based clustering of publications using CitNetExplorer and VOSviewer'', Scientometrics, 111: 1053-1070, (2017).
[28] Sajovic I. and Podgornik B., ''Bibliometric Analysis of Visualizations in Computer Graphics: A Study'', SAGE Open, 12, (2022).
[29] Ding X. and Yang Z., ''Knowledge mapping of platform research: a visual analysis using VOSviewer and CiteSpace'', Electronic Commerce Research, 1-23, (2020).
[30] Smyrnova-Trybulska E., Morze N., Kuzminska O. and Kommers P., ''Mapping and visualization: selected examples of international research networks'', Journal of Information, Communication and Ethics in Society, 16: 381-400, (2018).
[31] Van Eck N. and Waltman L., ''Software survey: VOSviewer, a computer program for bibliometric mapping'', Scientometrics, 84: 523-538, (2009).
[32] McAllister J., Lennertz L. and Mojica Z., ''Mapping A Discipline: A Guide to Using VOSviewer for Bibliometric and Visual Analysis'', Science & Technology Libraries, 41: 319-348, (2021).
[33] Rong J., ''Co-citation and Visualized Analysis of Literatures in Library and Information Science Based on Web of Science and VOSviewer'', Academic Journal of Humanities & Social Sciences, 7(8): 62-73, (2024).
[34] Borgohain D., Bhardwaj R. and Verma M., ''Computational Mapping of Indian Organic Chemistry Research: An Analysis with Data Mining Tools'', Journal of Scientometric Research, 13(1): 176-191, (2024).
[35] Tanwar M. and Verma H., ''Scientific Mapping of Chatbot Literature: A Bibliometric Analysis'', International Journal of Mathematical, Engineering and Management Sciences, 9(2): 323-340, (2024).
[36] Klarin A., ''How to conduct a bibliometric content analysis: Guidelines and contributions of content co‐occurrence or co‐word literature reviews'', International Journal of Consumer Studies, 48(2): e13031, (2024).
[37] Sheela S., Ali A., Tanaraj K. and Izani I., ''Navigating the Future: Blockchain’s Impact on Accounting and Auditing Practices'', Sustainability, 15(24): 16887, (2023).
[38] Fernandez-Rodriguez M. and Alvarez L., ''Microgels and Nanogels at Interfaces and Emulsions: Identifying Opportunities From a Bibliometric Analysis'', (2021).
[39] Bonilla-Chaves E. and Palos-Sánchez P., ''Exploring the Evolution of Human Resource Analytics: A Bibliometric Study'', Behavioral Sciences, 13(3): 244, (2023).
[40] Chen C., ''The centrality of pivotal points in the evolution of scientific networks'', Proceedings of the 10th International Conference on Intelligent User Interfaces, 98-105, (2005).
[41] Markscheffel B. and Schröter F., ''Comparison of two science mapping tools based on software technical evaluation and bibliometric case studies'', COLLNET Journal of Scientometrics and Information Management, 15: 365-396, (2021).
[42] Stojanović A., ''Knowledge mapping of research on Industry 4.0: A visual analysis using CiteSpace'', Serbian Journal of Management, 17(1): 125-143, (2022).
[43] Anish R. A., S. J., Jose J., P. N. and Joseph A., ''Navigating the Web of Influence: A Bibliometric Analysis of Social Media Addiction'', Cureus, 16(6), (2024).
[44] Chen C. and Song M., ''Science Mapping Tools and Applications'', Representing scientific knowledge: The role of uncertainty, 57-137, (2017).
[45] Barbu L., Mihaiu D., Serban R. and Opreana A., ''Knowledge Mapping of Optimal Taxation Studies: A Bibliometric Analysis and Network Visualization'', Sustainability, 14(2): 1043, (2022).
[46] Cui Y., Mou J. and Liu Y., ''Knowledge mapping of social commerce research: a visual analysis using CiteSpace'', Electronic Commerce Research, 18: 837-868, (2018).
[47] Cobo M., López-Herrera A., Herrera-Viedma E. and Herrera F., ''SciMAT: A new science mapping analysis software tool'', Journal of the Association for Information Science and Technology, 63: 1609-1630, (2012).
[48] Vasconcelos L., Sigahi T., De Souza Pinto J., Rampasso I. and Anholon R., ''Supply chain management maturity and business models: scientific mapping using SciMAT'', Benchmarking: An International Journal, 32(1): 26-51, (2023).
[49] Rincon-Patino J., Ramírez-González G. and Corrales J., ''Exploring machine learning: A bibliometric general approach using SciMAT'', F1000Research, 7: 1210, (2018).
[50] Morooka F., Manoel A., Sigahi T., De Souza Pinto J., Rampasso I. and Anholon R., ''Deep Learning and Autonomous Vehicles: Strategic Themes, Applications and Research Agenda Using SciMAT and Content-Centric Analysis, a Systematic Review'', Machine Learning and Knowledge Extraction, 5: 763-781, (2023).
[51] Ruiz-Rosero J., Ramírez-González G. and Viveros-Delgado J., ''Software survey: ScientoPy, a scientometric tool for topics trend analysis in scientific publications'', Scientometrics, 121: 1165-1188, (2019).
[52] Bador E., Abdel-Magid I., Ahmad S. and Akhter M., ''Bibliometric Analysis of Wastewater Literature Published in Web of Science 2019 to 2020'', Library Philosophy and Practice, 1-21, (2020).
[53] Ishak N. S., Roslan M. F. and Abdullah K. H., ''Bibliometric analysis of Malaysian authorship: Trends, patterns and prospects'', Asian Journal of Research in Education and Social Sciences, 5(2): 33-44, (2023).
[54] Barzehkar M., Parnell K., Soomere T., & Koivisto M. ''Offshore wind power plant site selection in the Baltic Sea'', Regional Studies in Marine Science, 73: 103469, (2024).
[55] Ren Z., Zhang S., Su Y., Yao Z., Huang R., & Wang P., ''Low-carbon policy simulation for offshore wind power development in China's net-zero power sector'', Energy Policy, 205: 114700, (2025).
[56] Barooni M, Ashuri T, Velioglu Sogut D, Wood S, Ghaderpour Taleghani S., ''Floating Offshore Wind Turbines: Current Status and Future Prospects'', Energies, 16(1): 2, (2023).
[57] Galparsoro I., Menchaca I., Garmendia J. M., Borja Á., Maldonado A. D., Iglesias G., & Bald J., ''Reviewing the ecological impacts of offshore wind farms'', npj Ocean Sustainabiltiy, 1: 1, (2022).
[58] Cutajar C, Sant T, Aquilina L, Buhagiar D, Baldacchino D., ''Subsea Long-Duration Energy Storage for Integration with Offshore Wind Farms'', Energies, 17(24): 6405, (2024).
[59] Rabanal A., Smith A. M., Ahaotu C. C., & Tedeschi E., ''Energy storage systems for services provision in offshore wind farms'', Renewable and Sustainable Energy Reviews, 200: 114573, (2024).
[60] Zhang H., Xiang W., & Wen J., ''Dual Grid-Forming Control With Energy Regulation Capability of MMC-HVDC System Integrating Offshore Wind Farms and Weak Grids'', IEEE Transactions on Power Systems, 39: 261-272, (2024).
[61] Hu H., Xue W., Jiang P., & Li, Y., ''Bibliometric analysis for ocean renewable energy: An comprehensive review for hotspots, frontiers, and emerging trends'', Renewable and Sustainable Energy Reviews, 167: 112739, (2022).
[62] Agyekum E. B., Khan T., Ampah J. D., Giri N. C., Mbasso W. F., & Kamel S., ''Review of the marine energy environment-a combination of traditional, bibliometric and PESTEL analysis'', Heliyon, 10(6), (2024).

Toplam 62 adet kaynakça vardır.

Ayrıntılar

Birincil Dil	Türkçe
Konular	Endüstri Mühendisliği
Bölüm	Araştırma Makalesi
Yazarlar	Esra Özkan Aksu 0000-0003-2142-2221 Cevriye Gencer 0000-0002-3373-8306
Erken Görünüm Tarihi	2 Haziran 2025
Yayımlanma Tarihi
Gönderilme Tarihi	9 Mart 2025
Kabul Tarihi	21 Mayıs 2025
Yayımlandığı Sayı	Yıl 2025 ERKEN GÖRÜNÜM

Kaynak Göster

APA	Özkan Aksu, E., & Gencer, C. (2025). Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler. Politeknik Dergisi1-1. https://doi.org/10.2339/politeknik.1653494
AMA	Özkan Aksu E, Gencer C. Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler. Politeknik Dergisi. Published online 01 Haziran 2025:1-1. doi:10.2339/politeknik.1653494
Chicago	Özkan Aksu, Esra, ve Cevriye Gencer. “Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları Ve Gelişen Eğilimler”. Politeknik Dergisi, Haziran (Haziran 2025), 1-1. https://doi.org/10.2339/politeknik.1653494.
EndNote	Özkan Aksu E, Gencer C (01 Haziran 2025) Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler. Politeknik Dergisi 1–1.
IEEE	E. Özkan Aksu ve C. Gencer, “Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler”, Politeknik Dergisi, ss. 1–1, Haziran 2025, doi: 10.2339/politeknik.1653494.
ISNAD	Özkan Aksu, Esra - Gencer, Cevriye. “Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları Ve Gelişen Eğilimler”. Politeknik Dergisi. Haziran 2025. 1-1. https://doi.org/10.2339/politeknik.1653494.
JAMA	Özkan Aksu E, Gencer C. Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler. Politeknik Dergisi. 2025;:1–1.
MLA	Özkan Aksu, Esra ve Cevriye Gencer. “Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları Ve Gelişen Eğilimler”. Politeknik Dergisi, 2025, ss. 1-1, doi:10.2339/politeknik.1653494.
Vancouver	Özkan Aksu E, Gencer C. Deniz Üzeri Rüzgâr Enerjisi Bibliyometrik Analizi: Öncelikli Araştırma Alanları ve Gelişen Eğilimler. Politeknik Dergisi. 2025:1-.

Makale Dosyaları

Tam Metin

TARANDIĞIMIZ DİZİNLER (ABSTRACTING / INDEXING)

download Bu eser Creative Commons Atıf-AynıLisanslaPaylaş 4.0 Uluslararası ile lisanslanmıştır.