Ibrahim Yahya Hakeem | Engineering and Technology | Best Researcher Award

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Assoc. Prof. Dr. Ibrahim Yahya Hakeem | Engineering and Technology | Best Researcher Award

Assoc. Prof. Dr. Ibrahim Yahya Hakeem | Engineering and Technology | Best Researcher Award | Associate Professor | Najran University | Saudi Arabia 

Assoc. Prof. Dr. Ibrahim Yahya Hakeem is a highly accomplished scholar and Associate Professor of Structural Engineering, Building Materials, and Concrete Technology at Najran University, Saudi Arabia, where he has made significant contributions to civil and environmental engineering education and research. He holds a Ph.D. in Civil and Environmental Engineering from King Fahd University of Petroleum & Minerals (KFUPM), Saudi Arabia, where his doctoral research focused on developing sustainable and high-performance concrete materials. His academic foundation includes an M.Sc. in Civil and Environmental Engineering from KFUPM and a B.Sc. in Civil Engineering from Aden University, Yemen, both earned with high distinction and multiple honors. Over the years, Assoc. Prof. Dr. Ibrahim Yahya Hakeem has built an impressive professional career marked by excellence in teaching, research, and institutional leadership. He currently serves on several key committees at Najran University, including the Supreme Standing Committee for Renewing Institutional Accreditation, the Standing Committee for Program Accreditation, and the Executive Committee for Monitoring the Quality of Teaching and Learning. His professional expertise encompasses structural design, ultra-high-performance concrete (UHPC), sustainable construction materials, fiber-reinforced composites, and the use of industrial and agricultural waste for green concrete development. His active research projects—funded by national and institutional bodies—focus on eco-friendly, high-strength concrete formulations, advancing environmental sustainability in the construction sector. Assoc. Prof. Dr. Ibrahim Yahya Hakeem has demonstrated remarkable research skills in experimental design, finite element modeling, and materials characterization, complemented by his leadership as Principal Investigator in more than twenty funded projects. His strong publication record includes articles in high-impact journals indexed in Scopus, IEEE, and other prestigious databases, alongside patented innovations such as the “Flexural Hybrid Span Beam” and developments in sustainable ultra-high-performance concrete. His international collaborations with institutions like KFUPM and partnerships with industrial entities such as SABIC reflect his ability to integrate research, application, and innovation effectively. Recognized among the Top 2% World Scientists in Construction by Stanford University, Dr. Hakeem has also served as a certified academic reviewer for the National Center for Academic Accreditation and Evaluation (NCAAA). His numerous academic honors, leadership positions, and professional memberships underscore his ongoing commitment to academic excellence, sustainability, and research-driven education. In conclusion, Assoc. Prof. Dr. Ibrahim Yahya Hakeem stands out as a visionary academic leader whose sustained research productivity, innovative contributions, and institutional service continue to influence the global field of structural and materials engineering, promoting environmentally responsible construction practices and advancing engineering education standards worldwide.

Profile:  Scopus | ORCID | Google Scholar

Featured Publications 

  1. Hakeem, I. Y. (2025). Date palm fibers (from Najran city) as reinforcement in UHPC: Design, performance, and microstructural analysis. AIP Advances.

  2. Hakeem, I. Y. (2025). Flexural performance and ductility of UHPC incorporating Najran City’s lathe waste powder (LWP) for substitution of cement. Innovative Infrastructure Solutions.

  3. Hakeem, I. Y. (2025). Sustainable high strength polymer concrete with high ratios of recycled aggregate from different decades under heat curing. Revista Materia.

  4. Hakeem, I. Y. (2024). Corrigendum to “Experimental investigation and analytical verification of buckling of functionally graded carbon nanotube-reinforced sandwich beams.” Heliyon, 10(8), e28388.

  5. Hakeem, I. Y. (2023). Application of waste ceramic powder as a cement replacement in reinforced concrete beams toward sustainable usage in construction. Case Studies in Construction Materials, 19, e02444.

  6. Hakeem, I. Y. (2023). Effects of glass fiber on recycled fly ash and basalt powder-based geopolymer concrete. Case Studies in Construction Materials, 19, e02659.

  7. Hakeem, I. Y. (2014). Ultra-high performance concrete reinforcement bars. U.S. Patent Publication No. US20140190113A1.

 

Jialin Li | Environmental Science | Best Researcher Award

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Mr. Jialin Li | Environmental Science | Best Researcher Award

Doctor | Fudan university | China

Mr. Jialin Li is an accomplished researcher and Doctor at Fudan University, specializing in the preparation, functionalization, and application of advanced carbon-based porous materials for hydrogen storage, energy storage, and carbon dioxide capture. His educational background includes a master’s and doctorate in chemical engineering and materials science, where his primary focus was on nano-pore interface micro-environment regulation, design of multi-level nano-pore structures, and surface chemical modification of functional porous carbon fibers, carbon nanofibers, carbon aerogels, and porous carbon materials. Professionally, Mr. Jialin Li has been involved in significant research projects such as the coupling regulation of ultra-fine pores and hydrogen-bond microenvironment of polyacrylonitrile porous carbon nanofibers and investigating hydrogen adsorption mechanisms under confined conditions. He has made valuable contributions to material design strategies for energy applications and has played a key role in translating research findings into practical solutions, including patented technologies for preparing biomass textile fabric electrodes and pre-oxidized fiber fabric electrodes for flow batteries. As a dedicated researcher, Mr. Jialin Li has authored 14 documents, 124 citations, 6 h-index, which highlights his consistent research output and influence in the scientific community. His research has been widely published in reputable international journals, including the Chemical Engineering Journal, Journal of Colloid and Interface Science, ACS Nano, and International Journal of Hydrogen Energy, all indexed in Scopus and SCI, reflecting his ability to contribute to high-quality peer-reviewed publications. Mr. Jialin Li’s research interests include developing new porous carbon materials with ultra-high specific surface areas, improving gas adsorption performance at ambient conditions, and creating novel strategies for hydrogen and carbon dioxide storage. His research skills span advanced material synthesis, nano-structuring, micro-environment modulation, adsorption mechanism analysis, and interface chemical engineering, combined with hands-on experience in experimental design and data interpretation. He is also actively engaged in collaborative research that bridges chemistry, materials science, and environmental engineering, reflecting his interdisciplinary approach. Beyond his technical expertise, Mr. Jialin Li has contributed to mentoring younger researchers, fostering collaboration within his team, and supporting sustainable energy initiatives. His honors include recognition for scientific excellence through peer-reviewed publications, contribution to multiple high-impact studies, and the development of patented solutions that support energy sustainability.

Profile:  Scopus

Featured Publications

Li, J., Wang, Y., Zhang, Y., Zhao, W., Bao, W., Duan, Y., Yu, J., Zhu, B., & Qiao, K. (2024). Dipole-induced hydrogen bonds enhanced P/O co-doped Lyocell-based porous carbon fiber cloth for hydrogen storage under ambient pressure. Chemical Engineering Journal, 490, 151633. Citations: 35

Li, J., Duan, Y., Wang, Y., Zhang, Y., Zhou, J., Zhao, W., Yu, J., Zhu, B., & Qiao, K. (2024). Microenvironment modulation of interpenetrating-type hierarchical porous foam carbon by mild-homogeneous activation for H₂ storage and CO₂ capture under ambient pressure. Journal of Colloid and Interface Science, 675, 783–791. Citations: 28

Yu, J., Li, J., Chen, F., Chi, C., Zhang, W., Bao, W., Zhao, X., Zhu, B., & Qiao, K. (2024). Micro-nano scale synchronous “carving” of viscose fiber in activation process for atmospheric hydrogen storage. International Journal of Hydrogen Energy, 63, 411–417. Citations: 19

Zhang, Y., Zhu, B., Zhao, S., Zhao, W., Zhou, M., Sun, Y., Qiao, K., Liu, J., Zhou, J., & Li, J. (2024). In situ synthesis of self-assembly supramolecular crystal seeds within continuous carbon nanofibers for improved fiber graphitic structure. ACS Nano, 18(17), 11360–11374. Citations: 22

Bao, W., Yu, J., Chen, F., Du, H., Zhang, W., Yan, S., Lin, T., Li, J., Zhao, X., & Zhu, B. (2023). Controllability construction and structural regulation of metal-organic frameworks for hydrogen storage at ambient condition: A review. International Journal of Hydrogen Energy, 48(92), 36010–36034. Citations: 20

 

 

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

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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