Goknur Berber Narin | Engineering and Technology | Best Researcher Award

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Assist. Prof. Dr Goknur Berber Narin | Engineering and Technology | Best Researcher Award

Assist. Prof. Dr Goknur Berber Narin | Engineering and Technology | Best Researcher Award | Assistant Professor | Agrı Ibrahim Cecen University | Turkey 

Assist. Prof. Dr. Goknur Berber Narin is a Turkish civil engineer whose academic journey began with a Bachelor’s degree in Civil Engineering from Süleyman Demirel University, followed by a Master’s (thesis on logistics-hub site selection) and a Ph.D. (dissertation on modeling highway traffic noise) at Karadeniz Technical University. Professionally, she serves as Assistant Professor at Doğubayazıt Ahmedi Hani Vocational School, Ağrı İbrahim Çeçen University, where she teaches, supervises, and leads research projects. Her research interests center on transportation engineering, environmental noise modeling, logistics decision systems, and pavement performance, with a particular emphasis on how meteorological conditions, vehicle composition, and infrastructure types influence road noise and logistics hub siting. She is skilled in multi-criteria decision-making methods (AHP and Delphi), noise measurement and modeling, concrete durability assessment, and statistical and computational modeling. She has participated in several national research projects: for instance, she leads a TÜBİTAK-funded study on modeling road traffic noise under varying topography and meteorological conditions, and is a researcher on projects analyzing polypropylene fiber in concrete joints and ultrasonic testing of road concrete layers. Her work has been published in international refereed journals and presented at international conferences, demonstrating her active engagement in both theory and practice. Among her honors are the 2021 YTMK Master’s Thesis Award from the Turkish National Roads Committee and the EMAY Incentive Award from EMAY International Engineering & Consultancy, reflecting recognition for her academic excellence. She has also obtained multiple professional certifications, including training in traffic safety, geospatial data (GIS), environmental vibration measurement, damage detection in buildings, and advanced material testing, underscoring her commitment to both teaching and applied research. In conclusion, Assist. Prof. Dr. Goknur Berber Narin is a dedicated scholar whose rich educational background, project leadership, publication record, and cross-disciplinary skills make her a rising influence in sustainable infrastructure research and civil engineering education.

Profile: ORCID 

Featured Publications

  1. Berber, G., & Akpınar, M. V. (2024). Tırların Hıza Bağlı Olarak Oluşturduğu Çevresel Gürültünün İncelenmesi. International Journal of Advanced Natural Sciences and Engineering Researches.

  2. Berber, G., & Akpınar, M. V. (2024). Lojistik Merkez Yer Seçiminde Kullanılan AHP ve Delphi Yöntemlerinin Karşılaştırılması. International Journal of Advanced Natural Sciences and Engineering Researches.

  3. Kadıoğlu, T., Akpınar, M. V., & Berber, G. (2023). Asfalt ve Beton Kaplamaların Dayanım-Zaman Performansının İncelenmesi. Proceedings of the 2nd International Conference on Innovative Academic Studies.

  4. Berber, G., & Akpınar, M. V. (2024). Tırların Hıza Bağlı Olarak Oluşturduğu Çevresel Gürültünün İncelenmesi. 5th International Conference on Innovative Academic Studies.

  5. Berber, G., & Akpınar, M. V. (2024). Lojistik Merkez Yer Seçiminde Kullanılan AHP ve Delphi Yöntemlerinin Karşılaştırılması. 5th International Conference on Innovative Academic Studies.

  6. Kadıoğlu, T., Akpınar, M. V., & Berber, G. (2023). Investigation of the Performance of Polypropylene (PP) Fibers in Joints of Concrete Pavements. 3rd International Civil Engineering & Architecture Conference.

  7. Berber, G., Akpınar, M. V., & Kadıoğlu, T. (2023). Investigation of UK Noise Maps in the Highway Lgag Noise Parameter. 3rd International Civil Engineering & Architecture Conference.

 

Rongshun Chen | Engineering and Technology | Best Researcher Award

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Prof. Rongshun Chen | Engineering and Technology | Best Researcher Award

Prof. Rongshun Chen | Engineering and Technology | Best Researcher Award | Professor | National Tsing Hua University | Taiwan 

Prof. Rongshun Chen is a distinguished academic and accomplished researcher in the field of mechanical and power engineering, currently serving as a Professor in the Department of Power Mechanical Engineering at National Tsing Hua University, Hsinchu, Taiwan. Prof. Chen obtained his Bachelor of Science degree in Mechanical Engineering from the National Taiwan University of Science and Technology, followed by a Master of Science in Power Mechanical Engineering from National Tsing Hua University, and subsequently earned his Doctor of Philosophy in Mechanical Engineering from the University of Michigan, Ann Arbor, USA. Throughout his extensive academic career, Prof. Chen has made significant contributions to the advancement of robotics, control systems, and thermal management technologies, with a focus on developing intelligent sensing mechanisms, adaptive control, and mechatronic system integration. His research interests encompass robotics navigation, sensor technology, deep learning applications in thermal management, and micro-electromechanical systems (MEMS) design. Prof. Chen’s expertise extends across several domains of applied mechanics and computational modeling, enabling the development of efficient systems for industrial automation and energy-efficient engineering applications. His professional experience includes mentoring numerous graduate students, leading innovative research projects, and collaborating with interdisciplinary teams on global initiatives that bridge academia and industry. Prof. Chen has consistently demonstrated outstanding research skills in designing hybrid solvers for multi-agent motion control, developing dual-mode tactile sensors, and implementing deep learning models for predictive thermal management in data centers. His scholarly work has been published in high-impact journals and presented at major international conferences such as IEEE and Elsevier platforms, earning recognition for scientific rigor and innovation. A committed educator and leader, Prof. Chen is also an active member of the IEEE and has served in multiple academic and technical committees, contributing to the broader engineering research community. He has received numerous honors for his outstanding teaching and research achievements and continues to inspire through his leadership in robotics and thermal control engineering. Prof. Rongshun Chen’s career embodies the synergy of technical mastery, visionary thinking, and a lifelong dedication to advancing engineering science for societal benefit. His academic influence, publication record, and international collaborations firmly establish him as a leading scholar committed to advancing the future of intelligent mechanical systems and sustainable innovation through research excellence and mentorship.

Profile: Scopus | Google Scholar

Featured Publications

  1. Chen, R. (2022). Wearable and wireless performance evaluation system for sports science with an example in badminton. Scientific Reports. 7 citations.

  2. Chen, R. (2023). A Dual Spiral-Coils Tactile Sensor with Novel Driving Modes for Inductive Force and Capacitive Proximity Sensing. Conference Paper. 3 citations.

  3. Chen, R. (2023). Implementation of a Monolithic SoC Environmental Sensing Hub Using CMOS-MEMS Technique. Conference Paper. 1 citation.

  4. Chen, R. (2023). Collision-Free Navigation for Multiple Robots in Dynamic Environment. Conference Paper. 2 citations.

  5. Chen, R. (2023). Rack Inlet Temperature Prediction Based on Deep Learning. Conference Paper. 5 citations.

  6. Chen, R. (2023). A Dual Sensing Modes Capacitive Tactile Sensor for Proximity and Tri-Axial Forces Detection. Conference Paper. 12 citations.

 

Dr. Nematollah Fouladi | Engineering and Technology | Best Researcher Award

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Dr. Nematollah Fouladi | Engineering and Technology | Best Researcher Award

Assistant professor | Iranian Space Research Center | Iran

Dr. Nematollah Fouladi is an accomplished aerospace engineer and an innovative researcher whose scientific vision and technical mastery have significantly contributed to advancements in the field of aerospace propulsion and fluid dynamics. He currently serves as a Researcher at the Iranian Space Research Center, Tehran, where he leads and collaborates on cutting-edge projects focusing on high-altitude testing facilities, supersonic exhaust diffusers, and aerodynamic system optimization. Dr. Fouladi obtained his Ph.D. in Aerospace Engineering from Sharif University of Technology, Tehran, one of the most prestigious engineering universities recognized for its excellence in research and education. His academic journey has been distinguished by a strong focus on computational and experimental fluid mechanics, turbulence modeling, and supersonic flow control, all of which reflect his unwavering dedication to precision and scientific advancement. Throughout his career, Dr. Fouladi has demonstrated outstanding analytical and research capabilities, successfully integrating advanced simulation techniques with practical experimentation to develop efficient and reliable aerospace propulsion systems. His research interests lie primarily in the areas of aerothermodynamics, gas dynamics, high-altitude testing methodologies, and aerospace cooling system design, which play a critical role in improving the performance, safety, and sustainability of aerospace technologies. In addition to his technical expertise, Dr. Fouladi exhibits a strong command of numerical modeling, data interpretation, computational fluid dynamics (CFD), heat transfer analysis, and system integration, enabling him to contribute to interdisciplinary collaborations within international research networks. As an active contributor to scholarly communication, Dr. Nematollah Fouladi has authored 18 documents, garnered 109 citations, and achieved an h-index of 6, demonstrating his growing influence and recognition in the global aerospace research community. His works are published in leading peer-reviewed journals such as Physics of Fluids, Acta Astronautica, Aerospace Science and Technology, and Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering. These publications have provided valuable insights into high-speed flow behavior, diffuser performance, and nozzle optimization—offering practical solutions to aerospace challenges faced by industry and research institutions alike. Dr. Fouladi’s commitment extends beyond research as he actively participates in collaborative engineering projects, contributing to advancements in Iran’s aerospace infrastructure and capacity-building initiatives. His professional experience also includes involvement in experimental investigations that support national and international aerospace objectives, reinforcing his reputation as a reliable and forward-thinking engineer. He has demonstrated leadership qualities through mentoring emerging researchers, fostering innovation-driven research environments, and promoting scientific excellence across disciplines. Dr. Fouladi’s research skills encompass a comprehensive blend of theoretical analysis, computational proficiency, and experimental design—qualities that make his work both academically robust and practically relevant. His contributions have been recognized by academic and research communities, earning him honors and respect as a key figure in aerospace technology development.

Profile:  Google scholar | Scopus | ORCID

Featured Publications

  1. Fouladi, N. (2025). Cooling system design and analysis for high heat flux large dimension diffuser of a high-altitude test facility. International Journal of Thermofluids. (Cited by 5)

  2. Fouladi, N. (2024). Experimental evaluation of the influence of the diffuser inlet to nozzle exit cross sectional area ratio on pressure oscillation in a high-altitude test facility. Physics of Fluids. (Cited by 7)

  3. Fouladi, N. (2024). Gas dynamics at starting and terminating phase of a supersonic exhaust diffuser with a conical nozzle. Physics of Fluids. (Cited by 9)

  4. Fouladi, N. (2023). Experimental and comprehensive investigation of second throat diffuser area effect on ground test of a thrust optimized parabolic nozzle with different expansion ratios. Acta Astronautica. (Cited by 10)

  5. Fouladi, N. (2023). Starting transient analysis of second throat exhaust diffuser in high-altitude test of a thrust optimized parabolic nozzle. Physics of Fluids. (Cited by 6)

 

Lin Hua | Engineering and Technology | Excellence in Innovation Award

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Assoc. Prof. Dr. Lin Hua | Engineering and Technology | Excellence in Innovation Award

Assoc. Prof. Dr. Lin Hua | Engineering and Technology | Deputy Director | School of Naval Architecture | China 

Assoc. Prof. Dr. Lin Hua is a distinguished scholar in the field of marine engineering and structural integrity research. Her work focuses on understanding and predicting the fatigue life of marine structures under corrosive environments. With a strong academic foundation and a commitment to advancing engineering safety, she has become a recognized name for her contributions to pitting corrosion analysis and continuum damage mechanics modeling. Her research aims to bridge the gap between theoretical modeling and industrial applications, thereby improving the design, maintenance, and operational reliability of marine structures.

Professional Profile 

Education

Assoc. Prof. Dr. Lin Hua earned her doctoral degree in structural engineering from a leading university, where she developed expertise in continuum damage mechanics, fatigue analysis, and advanced computational modeling. Her educational background is complemented by rigorous research training, participation in collaborative projects, and specialized courses in marine structural health monitoring. This academic preparation laid the foundation for her groundbreaking work in fatigue crack initiation life prediction and pit morphology quantification.

Experience

Assoc. Prof. Dr. Lin Hua currently serves as an Associate Professor and leads several research initiatives focused on marine structural reliability. She has successfully collaborated with global research institutes, shipbuilding companies, and offshore engineering organizations to develop practical methodologies that improve the safety and performance of critical structures. Her extensive teaching portfolio includes mentoring graduate students and supervising doctoral dissertations, helping nurture the next generation of researchers. In addition, she has served on technical committees, participated in peer-review processes for high-impact journals, and contributed to the organization of international symposia on marine engineering.

Research Interest

Her primary research interests include fatigue life assessment of marine structures, pitting corrosion modeling, structural health monitoring, and life extension strategies for offshore platforms. She integrates theoretical modeling with computational techniques to predict fatigue crack initiation life under complex environmental conditions. Her recent work explores pit morphology parameters—size, shape, irregularity, and spacing—and their effects on structural integrity. By developing reliable mapping models and efficient numerical approaches, she provides industry stakeholders with actionable solutions to reduce maintenance costs, improve safety, and optimize lifecycle management.

Award

Assoc. Prof. Dr. Lin Hua has been recognized for her innovative contributions through institutional and international awards in the field of structural engineering and marine research. Her achievements include excellence awards for research impact, commendations for collaborative projects, and invitations to serve as a reviewer and advisor for prestigious journals. These accolades underscore her role as a leading researcher committed to advancing knowledge and delivering real-world engineering solutions.

Selected Publication

  • “Theoretical Mapping Model for Pit Morphology Parameters and Fatigue Crack Initiation Life” (Published: 2023, Citations: 45)

  • “Continuum Damage Mechanics-Based Numerical Approach for Marine Structure Life Assessment” (Published: 2022, Citations: 39)

  • “Multi-Factor Quantification of Pit Morphology and Its Effect on Fatigue Life” (Published: 2022, Citations: 31)

  • “Rapid Fatigue Life Prediction of Offshore Structural Components under Corrosive Conditions” (Published: 2021, Citations: 28)

Conclusion

Assoc. Prof. Dr. Lin Hua stands out as a pioneering researcher whose work addresses critical challenges in marine engineering and structural health assessment. Her integration of theoretical modeling, computational techniques, and practical validation has advanced understanding of fatigue life under corrosive conditions, providing a framework for safer marine operations. With a proven record of impactful publications, international collaborations, and mentorship, she continues to shape the future of structural engineering. Her dedication to bridging academic research with industrial application makes her a highly deserving candidate for prestigious awards, and her future research promises to further strengthen global standards in marine structural integrity and safety.

 

Lin Gu | Advanced Materials Engineering | Best Researcher Award

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Lin Gu | Advanced Materials Engineering | Best Researcher Award

 Lin Gu, Fudan University, China

Dr. Lin Gu is a distinguished researcher in wide bandgap semiconductor materials, particularly Ga2O3-diamond composites. He earned recognition with the National Scholarship for Master’s Students at Fudan University (2021-2022) and has authored over 20 influential papers in top journals like Nano Energy and Applied Surface Science. Notable works include research on thermal management and heat transfer in semiconductor materials. Dr. Gu received multiple awards, including Fudan University’s Professional Master’s Excellent Academic Scholarship and the Outstanding Graduate of Shanghai award. His dedication, collaborative spirit, and impactful research make him a leading figure in material science. 📚🔬🏅

Publication  Profile

oricid

Educational Background

Dr. Lin Gu earned the prestigious National Scholarship for Master’s Students during his time at Fudan University in 2021-2022. His research focuses on enhancing semiconductor materials, particularly Ga2O3-diamond composites. His work tackles crucial challenges in thermal management and interfacial heat transfer, aiming to improve the performance of high-power electronics. By addressing these key areas, Dr. Gu’s research has the potential to advance the efficiency and reliability of electronic devices, especially those operating under extreme conditions. His contributions are poised to make a significant impact in the field of semiconductor materials and electronic engineering.

Experience

Dr. Lin Gu is a dedicated engineer with extensive experience in wide bandgap semiconductor materials and processes 🌟🔬. From 2016 to 2021, he contributed significantly at Optorun (Shanghai) Co., Ltd. 💼. He actively participated in the prestigious Shanghai 2021 Science and Technology Innovation Action Plan 🚀📚. With over 20 published papers, including four as the first author and one as a co-corresponding author 📝📖, his academic contributions are noteworthy. He has also presented at esteemed conferences like IFWS and SSLCHINA in 2023, delivering oral and poster presentations 🎤📊. Currently, his collaborative work is under review in EES 🌐📑.

Awards and Recognition

Dr. Lin Gu is a distinguished researcher whose excellence has garnered widespread recognition. He earned the prestigious First Prize in Fudan University’s Professional Master’s Excellent Academic Scholarship for two consecutive academic years (2021-2023), reflecting his dedication and outstanding performance. In 2024, Dr. Gu was also honored as an Outstanding Graduate of Shanghai, further emphasizing his exceptional contributions to his field. His achievements are a testament to his academic excellence, commitment to research, and consistent drive for success. 🌟🎓🏆

Honors

Dr. Lin Gu is an outstanding academic achiever, having been awarded the prestigious National Scholarship for Master’s Students at the Industrial Technology Research Institute of Fudan University for the 2021-2022 academic year. 🏅 In recognition of his excellence, he won the first prize of Fudan University Professional Master’s Excellent Academic Scholarship for both the 2021-2022 and 2022-2023 academic years. 🏆 His dedication and hard work were further acknowledged when he was named an Outstanding Graduate of Shanghai in 2024. 🎓 These remarkable accomplishments reflect his commitment to academic excellence and research in his field. 🌟

Research Focus

Dr. Lin Gu’s research focuses on advanced materials science, particularly the synthesis and characterization of thin films and epitaxial layers using cutting-edge techniques such as Chemical Vapor Deposition (CVD) and Pulsed Laser Deposition (PLD). His work includes optimizing Ga₂O₃ films and heterostructures on diamond substrates, analyzing interfacial heat transfer, and enhancing material properties through annealing treatments. Key applications involve wide-bandgap semiconductors for optoelectronics and power devices. Dr. Gu contributes to understanding microstructural, optical, and chemical behaviors to advance high-performance materials. 🌟🔬📏 His studies are pivotal for developing next-generation electronic components and energy-efficient technologies. 🌍⚡💡

Publication Top Notes

Insights into the effect of susceptor rotational speed in CVD reactor on the quality of 4H-SiC epitaxial layer on homogeneous substrates

The Influence of Annealing Temperature on the Interfacial Heat Transfer in Pulsed Laser Deposition-Grown Ga2O3 on Diamond Composite Substrates

Optimization of Heteroepitaxial Gallium Oxide Thin Films on Diamond Composite Substrates using Pulsed Laser Deposition Method

Investigation of gallium oxide thin film hetero-integrated with bulk diamond via atomic layer deposition

Influence of Nitrogen Annealing Treatment on Optical, Microstructural, and Chemical Properties of Ga<sub>2</sub>O<sub>3</sub> Film Grown by Plasma-Enhanced Atomic Layer Deposition

Influence of Rapid Thermal Annealing on the Characteristics of Sn-Doped Ga2O3 Films Fabricated Using Plasma-Enhanced Atomic Layer Deposition