Tieliang Zeng | Electrical Engineering | Excellence in Researcher Award

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Mr. Tieliang Zeng | Electrical Engineering | Excellence in Researcher Award

Master’s Degree Candidate at The Electrical Engineering College, Guizhou University, China

Tieliang Zeng, a passionate and emerging researcher, is currently pursuing his master’s degree at the Electrical Engineering College, Guizhou University. With a sharp focus on power electronics, his specialization lies in parameter identification of power electronic converters using digital twin technology 🔧🧠. As part of his academic journey, he has contributed to the Guizhou Provincial Key Technology R&D Program ([2024] General 049) and has successfully published one SCI-indexed paper in an MDPI journal 📄. Though early in his career, Tieliang’s commitment to innovation and technical precision is evident through his focused academic work. His field of study is essential to developing smarter, more efficient power systems 🌐⚡. As a budding scholar with a futuristic vision, he aims to expand his research through collaboration, scientific rigor, and practical application. Zeng is certainly a name to watch in the rapidly evolving domain of intelligent electrical systems and digital modeling technologies. 🚀🔬

Professional Profile

ORCID Profile

🎓 Education 

Tieliang Zeng embarked on his higher education journey with an enduring curiosity for electrical systems and smart technologies ⚡📘. He is currently a master’s degree candidate at the Electrical Engineering College of Guizhou University, one of China’s respected institutions in engineering education. His academic path has been defined by a commitment to technical depth and an interest in bridging physical systems with digital simulations through digital twin frameworks 🖥️🔄. With courses covering power electronics, control systems, and system modeling, Tieliang has built a solid theoretical and practical base to support his research. His continuous engagement with both classroom knowledge and real-world problems reflects his drive to excel academically 🎯📚. He is particularly focused on mastering advanced tools and methods for parameter identification in complex converter systems, which forms the foundation of his graduate thesis and current research endeavors. Tieliang’s academic foundation is both robust and forward-thinking. 🧠🧮

💼 Professional Experience 

As a young professional rooted in academia, Tieliang Zeng has initiated his professional journey through research-intensive roles and scholarly projects 🧑‍🔬🔌. His main involvement lies with the Guizhou Provincial Key Technology R&D Program, where he contributes to solving real-world challenges in power electronics through modeling and parameter extraction techniques 📊🔍. Although he has not yet ventured into large-scale consultancy or industrial projects, his participation in a government-funded initiative is a strong testament to his applied research capabilities. Tieliang’s work often involves digital simulations, hardware experimentation, and analytical evaluations – skills that mirror the evolving demands of modern electrical engineering 🌐🔋. Despite being early in his career, his focused technical contributions and publishing experience underscore his potential to make meaningful impacts in both academic and industrial settings in the near future. He’s actively shaping himself as a future innovator in digital twin-based power systems. 🛠️📈

🔬 Research Interests 

Tieliang Zeng’s research compass is firmly directed toward parameter identification in power electronic converters, a core challenge in creating accurate digital twin models 🔄⚡. His exploration dives deep into understanding the dynamic behavior of power systems and how virtual replicas can be developed to monitor, simulate, and control them in real time 🌍🧪. This specialized interest enables improved performance, predictive maintenance, and enhanced design processes in modern electrical infrastructure. His methodology often blends simulation tools, mathematical modeling, and real-world data analysis to ensure accuracy and adaptability 🧠📐. With the energy sector moving rapidly toward smart and autonomous systems, Tieliang’s work is aligned with the global shift toward digitalization and sustainability 🔋🌱. He is eager to refine these models further, enabling high-efficiency and fault-tolerant systems. By focusing his research within this transformative domain, he contributes to the foundational knowledge necessary for tomorrow’s power solutions. 🧬📡

🏆 Awards and Honors 

While Tieliang Zeng has not formally listed any academic awards or honors as of now, his inclusion in a key provincial R&D project and the successful publication of an SCI-indexed paper reflect a merit-based recognition of his talent and research abilities 🧾🏅. Being part of a selective and competitive government-funded research program is in itself an acknowledgment of his capabilities as a skilled researcher 🎯🎓. These achievements at an early stage signal his potential to receive future distinctions as his academic and professional journey unfolds. His scholarly persistence and contribution to innovative topics like digital twins in power systems are laying the groundwork for academic excellence and institutional accolades. With such a trajectory, awards and honors seem to be only a matter of time. His current achievements already reflect a commendable level of discipline, originality, and technical maturity 🌟📘.

Publications Top Notes

  • Title: Digital Twin-Based Multi-Parameter Coordinated Identification Method for Three-Phase Four-Leg Converter

  • Authors: Tieliang Zeng, et al.

  • Journal: Electronics

  • Year: 2025

  • DOI: 10.3390/electronics14102002

  • ISSN: 2079-9292

  • Source: MDPI – Electronics Journal

Conclusion 

In conclusion, Tieliang Zeng stands as a dedicated and promising figure in the field of electrical engineering, particularly in the niche domain of digital twin-based parameter identification for power converters 🔌🧠. As a master’s student with strong research orientation, he is already contributing to meaningful scientific discourse through government-supported projects and peer-reviewed publications 📚💡. Although at the early stages of his career, his focused efforts, analytical mindset, and technical competence set a solid foundation for impactful research and future innovation. Tieliang’s ambitions clearly resonate with the global move toward smart grid solutions and digital infrastructure, positioning him as a valuable asset to both academia and industry 🌍🔬. His journey reflects the beginning of a career with significant potential, where theory and practical application merge to solve complex power challenges. With continued dedication and collaboration, Tieliang Zeng is poised to advance the next wave of digital electrical technologies. 🚀🔧

Elżbieta Jarzębowska | Engineering | Best Researcher Award

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Prof. Elżbieta Jarzębowska | Engineering | Best Researcher Award

Prof. Elżbieta Jarzębowska at Warsaw University of Technology, Poland

Prof. Elżbieta M. Jarzębowska 🇵🇱 is a distinguished academic at the Warsaw University of Technology 🏫, serving in the Institute of Aeronautics and Applied Mechanics ✈️. With a strong foundation in mechanical engineering ⚙️, her research spans multibody systems dynamics, nonlinear and geometric control 🧠, and robotics 🤖, including UAVs and space systems 🚀. She has contributed to major international projects in the USA 🇺🇸 and UK 🇬🇧, working with Ford Motor Company 🚗 and Cranfield University 🎓. Author of 150+ papers 📚, she is also a dedicated editor 📝 and member of top engineering societies like ASME and IFToMM 🌍.

Professional Profile:

Orcid

scopus

Google Scholar

🔹 Education and Experience 

🎓 Education

  • 🧠 B.S., M.S., Ph.D., D.Sc. in Mechanical Engineering from Warsaw University of Technology

  • 📚 Specialization in control and mechanics of constrained systems

💼 Experience

  • 🏫 Professor at Warsaw University of Technology

  • 🚗 Researcher at Ford Motor Company Research Laboratories, Dearborn, MI, USA

  • 🔧 Collaborator with Engineering Research Centre for Reconfigurable Machining Systems, University of Michigan

  • 🎓 Visiting researcher at Cranfield University, UK

  • 🌍 Member of Polish Academy of Sciences Committee of Mechanics, ASME, and IFToMM

🔹 Professional Development 

Prof. Jarzębowska has demonstrated exceptional growth through global collaboration 🌍, engaging in cutting-edge research in the US and UK. Her work with Ford Motor Company 🚙 and the University of Michigan 🧪 enhanced her real-world application of dynamic modeling and control theories. As an academic, she consistently contributes to curriculum development 📖, authorship, and editorial roles for high-impact journals 📝. Her active involvement in ASME, IFToMM, and Polish scientific communities 💼 showcases her commitment to lifelong learning and interdisciplinary exchange 🔄. She mentors young researchers 🎓 and advances mechanical control theory with every step 🚀.

🔹 Research Focus 

Prof. Jarzębowska’s research focuses on the modeling, dynamics, and control of multibody systems ⚙️, particularly those with constraints such as nonholonomic and underactuated systems 🔁. Her expertise extends to nonlinear and optimal control methods 🧠 applied to advanced robotic 🤖, aerospace ✈️, space 🚀, and underwater systems 🌊. Her work also involves geometric control theory 📐 and its integration into real-world applications like UAVs 🛸 and intelligent machines. By bridging fundamental theory with practical implementation 🔧, she addresses challenges in dynamic optimization, system stability, and intelligent control architectures across complex mechanical platforms 🌐.

🔹 Awards and Honors 

🏅 Member, Committee of Mechanics, Polish Academy of Sciences
🎖️ Associate Editor, Journal of Theoretical and Applied Mechanics
🏅 Associate Editor, ASME Journal of Computational and Nonlinear Dynamics
🏅 Associate Editor, Journal of Nonlinear Complex and Data Science
📘 Author of a monograph and numerous educational resources in mechanics
📚 Published over 150 research papers in international journals

Publication Top Notes

1. Application of Electroless Deposition for Surface Modification of the Multiwall Carbon Nanotubes

  • Journal: Chemical Physics Letters

  • Year: 2018

  • DOI: 10.1016/j.cplett.2018.04.056

  • Focus: Surface modification using electroless techniques applied to multiwall carbon nanotubes.

2. Hydrogen Disproportionation Phase Diagram and Magnetic Properties for Nd₁₅Fe₇₉B₆ Alloy

  • Journal: Journal of Rare Earths

  • Year: 2016

  • DOI: 10.1016/S1002-0721(16)60104-7

  • Focus: Thermodynamic and magnetic properties of a rare earth alloy involving hydrogen interactions.

3. Influence of Stirring Conditions on Ni/Al₂O₃ Nanocomposite Coatings

4. TEM & AFM – Complementary Techniques for Structural Characterization of Nanobainitic Steel

  • Journal: Archives of Metallurgy and Materials

  • Year: 2015

  • DOI: 10.1515/amm-2015-0278

  • Focus: Use of microscopy techniques to analyze nanobainitic steels.

5. Characterization of Nanobainitic Structure in 100CrMnSi6-4 Steel After Industrial Heat Treatment

  • Journal: Archives of Metallurgy and Materials

  • Year: 2014

  • DOI: 10.2478/amm-2014-0278

  • Focus: Microstructural evolution in high-strength steels after specific thermal treatments.

6. Influence of Milling Media on Mechanically Exfoliated MoS₂

  • Journal: Nanomaterials and Nanotechnology

  • Year: 2014

  • DOI: 10.5772/59903

  • Focus: Impact of milling conditions on the exfoliation efficiency of molybdenum disulfide.

7. Measurements of Strain in AlGaN/GaN HEMT Structures Grown by Plasma-Assisted MBE

  • Journal: Journal of Crystal Growth

  • Year: 2014

  • DOI: 10.1016/j.jcrysgro.2014.01.061

  • Focus: Strain analysis in GaN-based high-electron-mobility transistors using molecular beam epitaxy.

8. Nanobainitic Structure Recognition and Characterization Using Transmission Electron Microscopy

  • Journal: Archives of Metallurgy and Materials

  • Year: 2014

  • DOI: 10.2478/amm-2014-0277

  • Focus: Characterization of nanostructured steels via TEM.

9. HRTEM and LACBED of Zigzag Boundaries in GaN Epilayers

10. Identification of Phases in Alloy Steels After Quenching and Isothermal Quenching

Conclusion:

Prof. Elżbieta M. Jarzębowska stands out as a globally recognized, multidisciplinary researcher whose academic rigor, innovative contributions, and international impact make her an excellent candidate for the Best Researcher Award. Her blend of theoretical advancement and engineering application supports the highest standards of research excellence.

Guanqun Li | Engineering | Best Researcher Award

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Dr. Guanqun Li | Engineering | Best Researcher Award

Associate Researcher at Shengli oilfield, SINOPEC, China

Guanqun Li (李冠群), born in May 1994 in Shandong, China 🇨🇳, is an Associate Researcher at Shengli Oilfield Company, SINOPEC 🛢️. He earned his PhD in Oil and Gas Field Development Engineering from China University of Petroleum (East China) 🎓. His work focuses on the microscopic characterization of shale reservoirs and fluid dynamics in oil and gas systems 🔬💧. With numerous publications in top journals like Fuel and Physics of Fluids 📚, he brings innovation to shale oil recovery technologies. Passionate about fractal modeling and fluid imbibition research, Guanqun Li is contributing significantly to modern energy development ⚙️🌍.

Professional Profile:

Scopus

🔹 Education and Experience 

  • 🎓 Sep. 2016 – June 2019: Master’s in Oil and Gas Field Development Engineering, Yangtze University

  • 📚 Sep. 2019 – June 2023: PhD in Oil and Gas Field Development Engineering, China University of Petroleum (East China)

  • 🏢 July 2023 – Present: Associate Researcher, Shengli Oilfield Company, SINOPEC

🔹 Professional Development 

Dr. Guanqun Li 📘 has shown consistent professional growth, moving from academic research to applied industry innovation. His academic journey through Yangtze University and the China University of Petroleum provided a solid foundation in oilfield development ⚒️. At SINOPEC, he applies his expertise in reservoir simulation, fracturing mechanics, and fluid flow modeling 🔬. He actively contributes to peer-reviewed journals and international conferences 🌍. Guanqun continuously develops novel analytical and fractal models for imbibition in shale formations 🌀. His cross-disciplinary collaboration and technical excellence are hallmarks of his evolving career in the energy sector 🚀.

🔹 Research Focus Category 

Guanqun Li’s research centers on unconventional oil and gas recovery, specifically shale oil reservoir characterization and fluid imbibition mechanisms 🛢️💧. His work explores microscale fluid motion, fractal modeling, and productivity analysis in hydraulically fractured formations 🔍📈. He is especially interested in the spontaneous and forced imbibition processes in complex porous media under various boundary conditions 🧪. His models help optimize horizontal well performance and support enhanced oil recovery (EOR) strategies 🧠⚙️. With a clear focus on improving efficiency in volume fracturing and fluid migration mechanisms, his research is highly impactful in modern petroleum engineering 🚧.

🔹 Awards and Honors 

  • 🏅 Interpore Conference Presentation (2020) – Recognized for outstanding research on production enhancement in fractured wells

  • 📖 Multiple First-Author Publications – Published in top journals like Fuel, Physics of Fluids, and Energy & Fuels

  • 🧠 Acknowledged for Innovative Fractal Modeling – In spontaneous/forced imbibition in shale formations

  • 🥇 Highly Cited Review Paper – On EOR techniques in shale oil (Geofluids, 2021)

Publication Top Notes

  • Title: Quantifying lithofacies-dependent imbibition behavior in continental shale oil by fractal modeling: A case study of the gentle slope fault zone, Jiyang DepressionAuthors: Li Guanqun, Peng Yanxia, Yang Yong, Cao Xiaopeng, Su YuliangJournal: Fuel

    Year: 2025

Conclusion

Dr. Guanqun Li stands out as an emerging leader in petroleum reservoir engineering with clear scientific originality, engineering relevance, and a solid record of first-author publications in high-impact journals. His work has contributed meaningfully to advancing the understanding of shale oil imbibition mechanisms and their application in field operations.

Guanwei Jia | Engineering | Best Researcher Award

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Dr. Guanwei Jia | Engineering | Best Researcher Award

Associate Professor at Henan University, China

Guanwei jia (born in 1982) is an associate professor at the School of Physics and Electronics, Henan University, China. He holds a BSc in Electronic Information Engineering (2006), an MSc in Mechanical Engineering (2012), and a Ph.D. in Mechanical Engineering from Beihang University (2018). His research focuses on hydrogen-blended natural gas pipeline transportation and energy storage. By Spring 2025, he has 38 publications indexed in Web of Science. His contributions aim to enhance energy efficiency and sustainable energy solutions, making him a key figure in the field of energy engineering. 🔬⚡

Professional Profile:

Orcid

Education & Experience 🎓📜

  • BSc in Electronic Information Engineering – 2006 🎓📡

  • MSc in Mechanical Engineering – 2012 🛠️📊

  • Ph.D. in Mechanical Engineering (Beihang University) – 2018 🎓⚙️

  • Associate Professor, Henan University – Present 🎓🏛️

Professional Development 🚀🔍

Guanwei jia has significantly contributed to energy research, particularly in hydrogen-blended natural gas pipeline transportation and energy storage. His work integrates advanced mechanical engineering techniques with sustainable energy solutions. With 38 Web of Science-indexed publications, his research provides insights into energy optimization and pipeline safety. He collaborates with industry and academia to advance clean energy technologies. As an associate professor, he mentors students and leads research projects, fostering innovation in energy sustainability. His efforts in alternative energy solutions contribute to global efforts for a cleaner and more efficient energy future. 🔬⚡🌍

Research Focus 🔬⚡

Guanwei jia specializes in hydrogen-blended natural gas transportation and energy storage, addressing key challenges in pipeline safety, efficiency, and sustainability. His research explores how hydrogen integration in natural gas pipelines enhances energy efficiency while reducing carbon emissions. By leveraging mechanical engineering principles, he aims to develop secure and cost-effective storage solutions. His studies help advance the transition toward renewable energy, making natural gas pipelines adaptable for future hydrogen-based energy systems. His findings are valuable for energy infrastructure development, ensuring a safer, cleaner, and more efficient energy network for the future. ⚙️🌍⚡

Awards & Honors 🏆🎖️

  • 38 Web of Science-indexed publications 📑🔍

  • Recognized for contributions to hydrogen-blended gas research ⚡🔬

  • Active mentor and researcher in energy storage solutions 🎓📚

  • Key collaborator in sustainable energy initiatives 🌍🔋

Publication Top Notes

  1. “Water Vapour Condensation Behaviour within Hydrogen-Blended Natural Gas in Laval Nozzles”

    • Authors: Not specified in the provided information.

    • Journal: Case Studies in Thermal Engineering

    • Publication Date: March 2025

    • DOI: 10.1016/j.csite.2025.106064

    • Summary: This study investigates how water vapor condenses in hydrogen-blended natural gas as it flows through Laval nozzles. Understanding this behavior is crucial for optimizing nozzle design and ensuring efficient operation in systems utilizing hydrogen-enriched natural gas.

  2. “Simulation Study on Hydrogen Concentration Distribution in Hydrogen Blended Natural Gas Transportation Pipeline”

    • Authors: Not specified in the provided information.

    • Journal: PLOS ONE

    • Publication Date: December 3, 2024

    • DOI: 10.1371/journal.pone.0314453

    • Summary: This research employs simulations to analyze how hydrogen distributes within natural gas pipelines when blended. The findings provide insights into maintaining consistent hydrogen concentrations, which is vital for pipeline safety and efficiency.

  3. “Numerical Simulation of the Transport and Thermodynamic Properties of Imported Natural Gas Injected with Hydrogen in the Manifold”

    • Authors: Not specified in the provided information.

    • Journal: International Journal of Hydrogen Energy

    • Publication Date: February 2024

    • DOI: 10.1016/j.ijhydene.2023.11.178

    • Summary: This paper presents numerical simulations examining how injecting hydrogen into imported natural gas affects its transport and thermodynamic properties within a manifold. The study aims to inform strategies for integrating hydrogen into existing natural gas infrastructures.

  4. “Performance Analysis of Multiple Structural Parameters of Injectors for Hydrogen-Mixed Natural Gas Using Orthogonal Experimental Methods”

    • Authors: Not specified in the provided information.

    • Journal: Physics of Fluids

    • Publication Date: November 1, 2023

    • DOI: 10.1063/5.0175018

    • Summary: This study evaluates how various structural parameters of injectors influence the performance of hydrogen-mixed natural gas systems. Using orthogonal experimental methods, the research identifies optimal injector designs to enhance efficiency and reliability.

  5. “Ultrasonic Gas Flow Metering in Hydrogen-Mixed Natural Gas Using Lamb Waves”

    • Authors: Not specified in the provided information.

    • Journal: AIP Advances

    • Publication Date: November 1, 2023

    • DOI: 10.1063/5.0172477

    • Summary: This paper explores the application of Lamb waves in ultrasonic gas flow metering for hydrogen-mixed natural gas. The research demonstrates the effectiveness of this non-contact method in accurately measuring gas flow, which is essential for monitoring and controlling gas distribution systems.

Conclusion

While Guanwei Jia has made valuable contributions to the field of hydrogen energy and pipeline transportation, his suitability for a Best Researcher Award would depend on additional factors such as citations, research impact, industry collaborations, patents, and leadership in major projects. If he has demonstrated exceptional influence beyond publications—such as shaping energy policies, leading significant projects, or achieving high citation impact—he would be a strong candidate for the award.

Shirko Faroughi | Engineering | Best Researcher Award

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Prof. Shirko Faroughi | Engineering | Best Researcher Award

Academic at Urmia University of Technoloy, Iran

Dr. Shirko Faroughi, an esteemed Professor of Mechanical Engineering at Urmia University of Technology, Iran, specializes in Computational Mechanics, Isogeometric Analysis, and Finite Element Methods. With a Ph.D. from Iran University of Science and Technology, he has held research positions at KTH University (Sweden), Swansea University (UK), and Bauhaus University Weimar (Germany). His work spans fracture mechanics, machine learning, and 3D printing simulations. As a CICOPS Scholar at the University of Pavia, Italy, Dr. Faroughi actively collaborates on international research projects, contributing significantly to advanced numerical methods. 📚🌍

Professional Profile:

Scopus

Google Scholar

Education & Experience 🎓📜

  • Ph.D. in Mechanical Engineering (2010) – Iran University of Science and Technology 🏛️

  • M.S. in Mechanical Engineering (2005) – Iran University of Science and Technology 🏗️

  • B.S. in Mechanical Engineering (2003) – Tabriz University 🚗

🔹 Academic Roles

  • Professor (2020 – Present) – Urmia University of Technology 👨‍🏫

  • Associate Professor (2015 – 2020) – Urmia University of Technology 🔬

  • Assistant Professor (2011 – 2015) – Urmia University of Technology 📖

  • Visiting Researcher (2008 – 2009) – KTH University, Sweden 🇸🇪

🔹 Administrative & International Positions

  • Dean of Mechanical Engineering Department (2022 – Present) 🏢

  • CICOPS Scholar – University of Pavia, Italy (2022) 🇮🇹

  • Research Collaborator – Swansea University, UK (2015 – Present) 🇬🇧

  • Research Collaborator – New Mexico State University, USA (2016 – Present) 🇺🇸

  • Research Collaborator – Bauhaus University Weimar, Germany (2017 – Present) 🇩🇪

Professional Development 🌍📚

Dr. Shirko Faroughi has made remarkable contributions to mechanical engineering through computational mechanics, finite element analysis, and machine learning. His research advances superconvergent mass and stiffness matrices, isogeometric methods, phase-field methods, and energy harvesting. He also integrates AI-driven techniques to enhance engineering simulations. His collaborations span Europe and the U.S., working with top researchers on thin structures, 3D printing, and structural dynamics. As a department dean and international collaborator, he plays a pivotal role in engineering education and research innovations, fostering global academic partnerships. 🌎💡

Research Focus 🔍🧠

Dr. Faroughi’s research primarily revolves around Computational Mechanics and Advanced Numerical Methods, integrating Artificial Intelligence and Machine Learning for engineering applications. His work focuses on:

  • Superconvergent mass and stiffness matrices 📐🔬

  • Isogeometric and finite element methods 🏗️📊

  • Fracture mechanics and phase-field modeling 🏚️💥

  • Tensegrity structures and energy harvesting ⚡🔩

  • Machine learning and transfer learning in mechanical simulations 🤖📈

  • 3D printing simulations and advanced material modeling 🖨️🧩

His research bridges traditional mechanical engineering with AI and computational techniques, pushing engineering boundaries through innovative numerical simulations. 🚀🔢

Awards & Honors 🏆🎖️

  • CICOPS Scholarship – University of Pavia, Italy (2022) 🇮🇹

  • Visiting Researcher – KTH University, Sweden (2008-2009) 🇸🇪

  • Research Collaborator – Swansea University, UK (2015-Present) 🇬🇧

  • Research Collaborator – Bauhaus University Weimar, Germany (2017-Present) 🇩🇪

  • Research Collaborator – New Mexico State University, USA (2016-Present) 🇺🇸

  • Dean of Mechanical Engineering Department – Urmia University of Technology (2022-Present) 🏛️

  • Multiple Grants for Advanced Computational Mechanics Research 🎓🔍

Publication Top Notes

  1. Wave Propagation in 2D Functionally Graded Porous Rotating Nano-Beams

    • Authors: S. Faroughi, A. Rahmani, M.I. Friswell

    • Published in Applied Mathematical Modelling (2020)

    • Citations: 71

    • Focus: Investigates wave propagation in porous nano-beams using a general nonlocal higher-order beam theory, considering functionally graded materials and rotation effects.

  2. Vibration of 2D Imperfect Functionally Graded Porous Rotating Nanobeams

    • Authors: A. Rahmani, S. Faroughi, M.I. Friswell

    • Published in Mechanical Systems and Signal Processing (2020)

    • Citations: 54

    • Focus: Examines vibration behavior of imperfect functionally graded porous rotating nanobeams based on a generalized nonlocal theory.

  3. Non-linear Dynamic Analysis of Tensegrity Structures Using a Co-Rotational Method

    • Authors: S. Faroughi, H.H. Khodaparast, M.I. Friswell

    • Published in International Journal of Non-Linear Mechanics (2015)

    • Citations: 47

    • Focus: Develops a co-rotational method for analyzing nonlinear dynamics of tensegrity structures.

  4. Physics-Informed Neural Networks for Solute Transport in Heterogeneous Porous Media

    • Authors: S.A. Faroughi, R. Soltanmohammadi, P. Datta, S.K. Mahjour, S. Faroughi

    • Published in Mathematics (2023)

    • Citations: 40

    • Focus: Uses physics-informed neural networks (PINNs) with periodic activation functions to model solute transport in heterogeneous porous media.

  5. Nonlinear Transient Vibration of Viscoelastic Plates Using a NURBS-Based Isogeometric HSDT Approach

    • Authors: E. Shafei, S. Faroughi, T. Rabczuk

    • Published in Computers & Mathematics with Applications (2021)

    • Citations: 30

    • Focus: Investigates nonlinear transient vibrations of viscoelastic plates using an isogeometric high-order shear deformation theory (HSDT) approach.

Dalel Azaiez | Engineering | Best Researcher Award

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Ms. Dalel Azaiez | Engineering | Best Researcher Award 

Ms. Dalel Azaiez, Higher Institute of Technological Studies of Gafsa, Tunisia

Ms. Dalel Azaiez is a skilled geotechnical engineer and educator based at the Higher Institute of Technological Studies of Gafsa, Tunisia. With a Ph.D. in Geotechnical Engineering from the National Engineering School of Tunis, she has contributed to the field through both academic and practical applications, including the invention of the Cylindrical Shear Tool (TN 2020/0256). Her expertise spans civil engineering, soil mechanics, and quality control, and she brings practical knowledge to her teaching roles across several prestigious Tunisian institutions. Ms. Azaiez is proficient in technical tools such as Python, AutoCAD, and Arche Ossature, complemented by certifications in quality management and language proficiency.

PROFILE

Google  Scholar Profile

Scopus Profile

Educational Details

Ms. Dalel Azaiez is an accomplished academic and geotechnical engineer with a diverse background in civil engineering, teaching, and research innovation. She earned her Doctor of Philosophy in Geotechnical Engineering from the National Engineering School of Tunis (2015-2023), where she also contributed as a research engineer at SIMPRO, a firm specializing in geotechnical engineering. Her work led to the co-invention of the Cylindrical Shear Tool (TN 2020/0256), showcasing her drive for advancing practical applications in engineering. Ms. Azaiez’s earlier studies include a Civil Engineering degree from the National Engineering School of Sfax (2012-2015) and preparatory coursework in mathematics and physics at the Sfax Preparatory Engineering Institute, following her high school studies at Mohamed Ali Sfax.

Professional Experience

Ms. Azaiez has a rich teaching history across various esteemed institutions in Tunisia. Currently, she serves as a contract teacher at the Higher Institute of Technological Studies of Gafsa, where she instructs on quality control, computer-aided design, and project planning software, among other engineering-related topics. Her previous teaching roles include work as a temporary teacher at the Private Higher School of Engineering and Technology (ESPRIT), the Military Academy Fondouk El Jdid, and the National Engineering School of Tunis. Additionally, she taught practical classes in soil mechanics at the Higher Institute of Environmental Technologies, Urban Planning, and Building (ISTEUB).

Research Interest

Ms. Azaiez’s research is rooted in soil mechanics, materials testing, and innovative geotechnical engineering tools. Her contributions are marked by a strong focus on applying theoretical knowledge to solve real-world engineering problems, evident from her involvement in patenting the Cylindrical Shear Tool. Her technical acumen spans laboratory testing methods, geotechnics, and practical civil engineering applications.

Skills and Training

Her skill set includes proficiency in Python, AutoCAD 2D, and specialized engineering software like Arche Ossature. Ms. Azaiez is certified in ISO 9001 Quality Management and holds a DELF diploma, confirming her multilingual proficiency. Her continuous learning is exemplified by recent training in Python (2024), enhancing her technical and programming capabilities.

Ms. Azaiez’s academic, research, and teaching experiences underscore her commitment to geotechnical engineering and applied sciences, contributing to her impactful role in Tunisia’s higher education landscape.

Top Notable Publications

Azaiez, D., Boullosa Allariz, B., Levacher, D. (2024). Study of Physical and Mechanical Relationships during the Natural Dewatering of River Sediments and a Kaolin. Journal of Marine Science and Engineering, 12(8), 1354. Citations: 0.

Manigniavy, S.A., Bouassida, Y., Azaiez, D., Bouassida, M. (2023). Using Compression and Swelling Indices to Characterize Expansive Soils. Lecture Notes in Civil Engineering, 305, pp. 121–128. Citations: 1.

Bouassida, M., Azaiez, D. (2023). New Tool for the Measurement of Soils’ Shear Strength. Lecture Notes in Civil Engineering, 305, pp. 63–76. Citations: 0.

Azaiez, D., Bouassida, M. (2022). An Efficient Tool to Determine Undrained Shear Strength of Soft Soils. Geotechnical Engineering, 53(4), pp. 25–35. Citations: 0.

Bouassida, M., Manigniavy, S.A., Azaiez, D., Bouassida, Y. (2022). New Approach for Characterization and Mitigation of the Swelling Phenomenon. Frontiers in Built Environment, 8, 836277. Citations: 8.

Bouassida, M., Azaiez, D. (2019). On the Determination of Undrained Shear Strength from Vane Test. Sustainable Civil Infrastructures, pp. 50–68. Citations: 2.

Azaiez, D., Bouassida, M., Boullosa Allariz, B., Levacher, D. (2018). On the Characterization and Valorization of Sediments. 1st International Conference on Advances in Rock Mechanics, TuniRock 2018, pp. 133–142. Citations: 1.

Conclusion

Based on her academic qualifications, innovation in tool development, teaching experience, and research focus, Ms. Dalel Azaiez is a competitive candidate for the “Research for Best Researcher Award.” Her achievements and contributions highlight her dedication to advancing geotechnical engineering, which aligns well with the award’s focus on recognizing impactful research and practical innovation.

 

 

 

Yalini Devi Neelan | Engineering | Best Researcher Award

Published on by Physicist Particle

Dr. Yalini Devi Neelan | Engineering | Best Researcher Award

Google Scholar Profile

Educational Details

Dr. Yalini Devi Neelan completed her Ph.D. in Energy Harvesting Applications at Anna University, India, from 2016 to 2021. Her doctoral research focused on innovative methods for harnessing energy through advanced materials and nanotechnology. Prior to her Ph.D., she earned an M.Tech. in Nanoscience and Technology from Anna University, where she achieved an impressive GPA of 8.24/10 from 2014 to 2016. Dr. Neelan’s academic journey began with a Bachelor of Engineering in Electrical and Electronic Engineering, also from Anna University, where she graduated in 2014 with a GPA of 6.41/10. This solid educational background has equipped her with a strong foundation in both engineering principles and nanomaterials, driving her passion for research in energy solutions.

Research Experience

Dr. Yalini Devi Neelan is currently a Postdoctoral Researcher at the University of Milano, Italy, in the Thermoelectric’s Laboratory, where she focuses on the preparation and characterization of nanostructured silicon for thermoelectric applications. Her key responsibilities include preparing nanostructured materials, examining their physicochemical characteristics, and studying their Seebeck coefficient, electrical, and thermal conductivity to calculate the figure of merit (ZT). Prior to this, she was a Postdoctoral Researcher at Chungnam National University, South Korea, where she worked on nanostructured oxide-based materials for antibiotic degradation and battery applications, analyzing their photodegradation and electrochemical properties. Dr. Neelan also served as a Research Associate at Anna University, India, where she focused on energy harvesting and storage applications, preparing oxide-based nanomaterials and managing communications with funding agencies. During her Ph.D. at Anna University, she investigated nanostructured strontium titanate-based oxide thermoelectric materials for energy harvesting from waste heat. Additionally, she collaborated with Shimomura Laboratory at Shizuoka University, Japan, to enhance the thermoelectric power factor of nanostructured SrTiO3 through Gd and Nb co-substitution. Earlier in her academic journey, Dr. Neelan was a project student at the Indian Institute of Technology Madras, where she developed graphene oxide-based strain sensors for motion monitoring. Her diverse research experiences reflect her strong expertise in nanomaterials and energy applications.

Research Focus

Energy harvesting applications, particularly in thermoelectrics, focus on converting waste heat into usable electrical energy, thus promoting sustainable energy solutions. The synthesis of nanomaterials plays a crucial role in this field, as nanostructured materials exhibit enhanced thermoelectric properties due to their unique physical and chemical characteristics. These materials are engineered to optimize energy conversion efficiencies, allowing for effective harvesting from various heat sources. Additionally, advancements in energy storage applications complement energy harvesting by ensuring that the harvested energy can be effectively stored and utilized when needed. By integrating innovative synthesis techniques and exploring novel nanomaterials, researchers aim to improve the performance and efficiency of thermoelectric devices, ultimately contributing to a more sustainable and energy-efficient future.

Top Notable Publications

Enhancing effects of Te substitution on the thermoelectric power factor of nanostructured SnSe₁₋ₓTeₓ
Authors: D. Sidharth, A.S.A. Nedunchezhian, R. Rajkumar, N.Y. Devi, P. Rajasekaran, et al.
Journal: Physical Chemistry Chemical Physics
Year: 2019
Citations: 32

Effect of Gd and Nb co-substitution on enhancing the thermoelectric power factor of nanostructured SrTiO₃
Authors: N.Y. Devi, K. Vijayakumar, P. Rajasekaran, A.S.A. Nedunchezhian, et al.
Journal: Ceramics International
Year: 2021
Citations: 26

Enhanced thermoelectric performance of band structure engineered GeSe₁₋ₓTeₓ alloys
Authors: D. Sidharth, A.S.A. Nedunchezhian, R. Akilan, A. Srivastava, B. Srinivasan, et al.
Journal: Sustainable Energy & Fuels
Year: 2021
Citations: 25

Enhancement of thermoelectric power factor of hydrothermally synthesised SrTiO₃ nanostructures
Authors: N.Y. Devi, P. Rajasekaran, K. Vijayakumar, A.S.A. Nedunchezhian, et al.
Journal: Materials Research Express
Year: 2020
Citations: 15

Biogenic synthesis and characterization of silver nanoparticles: evaluation of their larvicidal, antibacterial, and cytotoxic activities
Authors: S. Mahalingam, P.K. Govindaraji, V.G. Solomon, H. Kesavan, Y.D. Neelan, et al.
Journal: ACS Omega
Year: 2023
Citations: 11

Effect of Bismuth substitution on the enhancement of thermoelectric power factor of nanostructured BiₓCo₃₋ₓO₄
Authors: A.S.A. Nedunchezhian, D. Sidharth, N.Y. Devi, R. Rajkumar, P. Rajasekaran, et al.
Journal: Ceramics International
Year: 2019
Citations: 11

Effective Visible-Light-Driven Photocatalytic Degradation of Harmful Antibiotics Using Reduced Graphene Oxide-Zinc Sulfide-Copper Sulfide Nanocomposites as a Catalyst
Authors: J.K. Shanmugam Mahalingam, Yalini Devi Neelan, Senthil Bakthavatchalam, et al.
Journal: ACS Omega
Year: 2023
Citations: 10

Enhancing the thermoelectric power factor of nanostructured ZnCo₂O₄ by Bi substitution
Authors: A.S.A. Nedunchezhian, D. Sidharth, R. Rajkumar, N.Y. Devi, K. Maeda, et al.
Journal: RSC Advances
Year: 2020
Citations: 7

High thermoelectric power factor of Ag and Nb co-substituted SrTiO₃ perovskite nanostructures
Authors: N.Y. Devi, A.S.A. Nedunchezhian, D. Sidharth, P. Rajasekaran, et al.
Journal: Materials Chemistry and Physics
Year: 2023
Citations: 3