Hamid El Qarnia | Heat Transfer Energy | Best Researcher Award

Published on by Metallurgical Engineering

Best Researcher Award

Hamid El Qarnia
Cadi Ayyad University, Morocco
Hamid El Qarnia
Affiliation Cadi Ayyad University
Country Morocco
Scopus ID 6507446902
Documents 45
Citations 1,383
h-index 15
Subject Area Heat Transfer-Energy
Event Metallurgical Engineering Awards
ORCID 0000-0002-3134-9825

Hamid El Qarnia is a Moroccan academic researcher and professor affiliated with Cadi Ayyad University. His scholarly activities focus on heat transfer, thermal energy storage systems, phase change materials, solar energy systems, computational fluid dynamics, thermodynamics, and advanced cooling technologies. Through decades of teaching, supervision, research publication, and international collaboration, he has contributed to the advancement of thermal sciences and energy engineering applications. His publication record, citation impact, editorial service, and conference leadership demonstrate sustained engagement with the international scientific community.[1][2]

Abstract

The Best Researcher Award recognizes sustained scholarly achievement, scientific productivity, and measurable research impact. Hamid El Qarnia has established a research profile centered on thermal engineering, heat transfer, phase change materials, latent heat storage technologies, and energy conversion systems. His academic career includes extensive teaching, graduate supervision, scientific publishing, conference leadership, editorial activities, and international collaboration. His research has contributed to improved understanding of thermal storage systems, melting and solidification processes, and advanced cooling technologies relevant to energy and engineering applications.[1][3]

Keywords

Heat Transfer; Thermal Energy Storage; Phase Change Materials; Computational Fluid Dynamics; Energy Conversion; Solar Energy Systems; Melting and Solidification; Thermal Management; Heat Exchangers; Metallurgical Engineering Applications.

Introduction

Research in thermal sciences plays an important role in advancing energy efficiency, industrial processes, and sustainable engineering solutions. Hamid El Qarnia has developed a long-standing academic career dedicated to investigating thermal phenomena in engineering systems, with particular emphasis on heat transfer mechanisms and energy storage technologies. His work combines analytical, numerical, and computational approaches to address practical challenges associated with energy utilization and thermal management.[1][2]

Research Profile

Hamid El Qarniapr earned a doctorate in Energetics from Cadi Ayyad University and later completed a Ph.D. in Mechanical Engineering at the University of Sherbrooke, Canada. His academic career spans more than three decades of teaching and research. Throughout this period, he has served in various academic roles, including assistant professor, associate professor, full professor, research assistant, and visiting academic collaborator. His professional activities extend beyond teaching to include research supervision, editorial responsibilities, conference organization, and scientific peer review.[2]

Research Contributions

Hamid El Qarnia’s research addresses the thermal behavior of phase change materials and latent heat storage systems. His investigations explore melting and solidification mechanisms, thermal performance optimization, and energy storage efficiency. These studies contribute to the development of advanced thermal management systems applicable to renewable energy technologies, industrial heat recovery, and cooling systems.[3][4]

Publications

Selected recent publications demonstrate continuing research activity in thermal engineering and energy storage technologies:

  1. Sustainable Thermal Insulation Composites Based on Alfa Plant Fibers and Wood Waste (2025).
  2. 3D Two Phases Reduced Model of a Rock Bed Thermocline Thermal Energy Storage Unit (2025).
  3. Acoustic, Mechanical and Thermal Characterization of Bio-Based Wood Composites Reinforced with Beech and Oak Fibers (2025).

Research Impact

The available bibliometric indicators demonstrate a measurable scholarly impact. With more than one thousand citations and an established h-index, Hamid El Qarnia’s work has received recognition within the thermal sciences and energy engineering communities. His contributions have supported academic discourse in energy storage, heat transfer enhancement, and sustainable engineering technologies. Beyond publication activity, his service as reviewer, editor, conference organizer, and scientific committee member reflects continued engagement in research leadership and knowledge dissemination.[1][2]

Award Suitability

The Best Researcher Award recognizes individuals who demonstrate sustained research productivity, scientific influence, scholarly leadership, and meaningful contributions to their academic discipline. Hamid El Qarnia’s career aligns with these criteria through extensive publication activity, international collaborations, graduate mentorship, editorial service, conference leadership, and impactful research addressing contemporary challenges in thermal energy systems. His multidisciplinary contributions to heat transfer and energy storage technologies support the objectives of scientific advancement and engineering innovation within the broader metallurgical and energy engineering domains.[2][5]

Conclusion

Hamid El Qarnia has developed a distinguished academic profile characterized by long-term engagement in research, teaching, supervision, and scientific service. His work in heat transfer, thermal energy storage, and phase change materials has contributed to the advancement of thermal engineering knowledge and practical energy applications. Considering his publication record, citation impact, professional leadership, and sustained research activity, he represents a strong candidate for recognition through the Best Researcher Award.[1][2]

References

  1. Elsevier. (n.d.). Scopus author details: Hamid El Qarnia, Author ID 6507446902. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=6507446902
  2. H El Qarnia, El Qarnia., & EK Lakhal. (2011). Thermal performance of a greenhouse with a phase change material north wall.
    https://www.uca.ma/fssm/fr
  3. Rbiyah, O., El Qarnia, H., Fedele, L., Bobbo, S., & Rossi, S. (2025). Investigation of Melting Process in a Double Tube Energy Storage Unit.
    https://doi.org/10.1109/SmartAgriSuSY68475.2025.11467033
  4. Ennaya, O., El Qarnia, H., & Arıcı, M. (2026). Analytical Solution for the Solidification of a Liquid in Couette Flow.
    https://doi.org/10.1002/est2.70386
  5. Mustapha Faraji, Hamid El Qarnia. (2009). Passive cooling of protruding electronic components by latent heat of fusion storage.
    https://asmedigitalcollection.asme.org/electronicpackaging/article-abstract/131/2/021011/466128

Mudassir Hussain Tahir | Pyrolysis | Best Researcher Award

Published on by Metallurgical Engineering

Dr. Mudassir Hussain Tahir | Pyrolysis | Best Researcher Award

Associate Professor at Nanjing Forestry University | China

Dr. Mudassir Hussain Tahir is a highly accomplished researcher whose prolific scientific contributions and multidisciplinary impact make him an exceptional candidate for the Best Researcher Award. With 2,411 citations, 119 peer-reviewed publications, and an impressive Scopus h-index of 27, he has established a strong global research footprint in biomass thermochemical conversion, catalytic pyrolysis, heterogeneous catalyst development, sustainable hydrogen-rich syngas production, CO₂ adsorption, bio-based chemical synthesis, and machine-learning-assisted materials discovery. His work has advanced fundamental understanding of pyrolysis kinetics, reactor design, catalyst–feedstock interactions, and waste-to-energy pathways, leading to high-value bio-oils, green chemicals, and sustainable aviation fuel precursors. He has published influential articles in leading journals such as Energy & Fuels, Bioresource Technology, Fuel, International Journal of Hydrogen Energy, Journal of Analytical and Applied Pyrolysis, ACS Omega, and Applied Thermal Engineering, covering both experimental innovation and computational materials design. His research also integrates advanced data-driven methodologies for designing organic semiconductors, dyes, polymers, and photovoltaic materials, positioning him at the frontier of clean energy materials research. In addition to his extensive publication record, he has served as Guest Editor and Review Editor for reputable journals, reflecting strong leadership and recognition within the scientific community. His contributions span renewable energy, waste valorization, catalysis, environmental sustainability, and predictive materials chemistry, demonstrating both depth and breadth in research excellence. Dr. Tahir’s sustained scholarly productivity, high citation impact, and transformative contributions to biomass energy and materials innovation exemplify the qualities of a distinguished and forward-thinking scientist, making him thoroughly deserving of the Best Researcher Award.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

Dechao Chen | Electrocatalysts | Best Researcher Award

Published on by Metallurgical Engineering

Dr. Dechao Chen | Electrocatalysts | Best Researcher Award

Postdoctoral Researcher at Fujian Institute of Research on the Structure of Matter Chinese Academy of Sciences | China

Dr. Dechao Chen is a postdoctoral researcher at the State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences. He has developed expertise in energy chemistry and environmental catalysis, with a strong focus on electrochemical devices and catalytic mechanisms. His academic journey has been marked by rigorous training and innovative contributions to advanced materials and sustainable catalytic systems. Dr. Chen has authored impactful publications in high-impact journals such as Advanced Materials, Nano Letters, Small, and Chemical Engineering Journal. His work explores critical areas including C–N coupling, ammonia synthesis, CO₂ reduction, and hydrogen production. He has also been awarded support from the China Postdoctoral Science Foundation to further develop single-atom catalyst research. Driven by curiosity and dedication, Dr. Chen aims to bridge fundamental science with practical applications to address pressing global energy and environmental challenges.

Professional Profile

Scopus | Google Scholar | ORCID

Education

Dr. Dechao Chen pursued his academic studies with a strong foundation in physics, materials science, and catalysis. He earned his Bachelor of Science degree in Physics and Information Engineering from Minnan Normal University, where he trained under the mentorship of Prof. Zhouan Zhou. His undergraduate work laid the groundwork for his interest in materials chemistry and catalysis. He then advanced his academic career at Hunan University, completing his Ph.D. in Materials Science and Engineering under the guidance of Prof. Yongwen Tan. During his doctoral studies, he focused on nanostructured metal compounds, electrocatalysis, and the development of novel energy conversion materials. His dissertation involved exploring nanoporous two-dimensional materials and electrocatalytic mechanisms for nitrogen reduction and hydrogen evolution. Dr. Chen’s educational journey provided him with extensive expertise in materials synthesis, advanced characterization techniques, and catalytic processes, shaping him into a skilled researcher capable of addressing challenges in sustainable energy.

Experience

Dr. Dechao Chen has gained valuable research experience through academic and institutional roles in materials science and electrochemistry. Currently, he serves as a postdoctoral researcher at the State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, working under Prof. Lili Han. His postdoctoral research emphasizes surface stress regulation and electrocatalytic CO₂ reduction using single-atom catalysts, supported by funding from the China Postdoctoral Science Foundation. Prior to this, his doctoral research at Hunan University focused on nanoporous two-dimensional compounds with three-dimensional bicontinuous structures, as well as innovative strategies for scalable doping and alloying in transition metal dichalcogenides. He has also conducted collaborative work on gold- and ruthenium-based catalytic systems for nitrogen reduction and hydrogen production. With broad expertise in nanomaterials synthesis, structural analysis, and catalytic applications, Dr. Chen has established himself as a promising researcher in electrochemical energy conversion and environmental catalysis.

Awards and Honors

Dr. Dechao Chen has been recognized for his outstanding contributions to materials science and electrochemical catalysis through significant academic achievements. He received support from the prestigious China Postdoctoral Science Foundation to conduct research on surface stress regulation and CO₂ electroreduction using single-atom catalysts. His publications in highly ranked international journals, including Advanced Materials, Nano Letters, Small, and the Chemical Engineering Journal, serve as testament to his scholarly excellence and innovative contributions. His work has attracted recognition from the global scientific community, highlighting the relevance and originality of his research in energy chemistry and sustainable catalysis. While early in his career, his growing record of publications and funded research demonstrates his potential to achieve further honors and leadership roles in the future. Dr. Chen’s academic trajectory continues to establish him as an emerging figure in his field.

Research Focus

Dr. Dechao Chen’s research focuses on energy chemistry, environmental catalysis, and electrochemical devices. His work spans the development of advanced catalytic systems for C–N coupling, ammonia synthesis, water electrolysis, hydrogen evolution, and CO₂ reduction. He is particularly interested in the design and regulation of single-atom and dual-atom catalysts to optimize catalytic activity and selectivity. His doctoral and postdoctoral studies have also explored the synthesis of nanoporous two-dimensional metal compounds with bicontinuous three-dimensional structures, aiming to enhance surface area, electronic conductivity, and reaction kinetics. Additionally, he investigates the catalytic mechanisms underlying nitrogen reduction and hydrogen production, providing fundamental insights that guide material innovation. By combining advanced materials synthesis, state-of-the-art characterization techniques, and theoretical understanding, his research aims to address urgent global challenges in sustainable energy conversion and environmental remediation. Ultimately, Dr. Chen’s research contributes to advancing green chemistry solutions for next-generation energy technologies.

Publication top Notes

Rational strain engineering of single-atom ruthenium on nanoporous MoS₂ for highly efficient hydrogen evolution
Year: 2021
Citations: 344

Spontaneous Atomic Ruthenium Doping in Mo₂CTX MXene Defects Enhances Electrocatalytic Activity for the Nitrogen Reduction Reaction
Year: 2020
Citations: 320

Identifying Electrocatalytic Sites of the Nanoporous Copper–Ruthenium Alloy for Hydrogen Evolution Reaction in Alkaline Electrolyte
Year: 2020
Citations: 297*

Single-Atom Gold Isolated Onto Nanoporous MoSe₂ for Boosting Electrochemical Nitrogen Reduction
Year: 2022
Citations: 102

Efficient electrosynthesis of formamide from carbon monoxide and nitrite on a Ru-dispersed Cu nanocluster catalyst
Year: 2023
Citations: 82

Scalable synthesis of nanoporous boron for high efficiency ammonia electrosynthesis
Year: 2020
Citations: 41

Conclusion

Dr. Dechao Chen is a highly suitable candidate for the Best Researcher Award. His strong record of publications in top-tier journals, independent research funding, and contributions to the fields of electrocatalysis and sustainable energy place him among the most promising young researchers in materials science. With continued emphasis on industrial translation, leadership development, and innovation beyond academia, he is well-positioned to become a leading figure in his discipline. His profile reflects both scientific excellence and future potential, making him a compelling choice for this recognition.