Zhenqian Zhang | Light-Matter Interactions | Best Researcher Award

Published on by Biophotonics Research

Dr. Zhenqian Zhang | Light-Matter Interactions | Best Researcher Award

Dr. Zhenqian Zhang | Hangzhou Dianzi University | China 

Dr. Zhenqian Zhang is an Assistant Researcher and Master’s supervisor at Hangzhou Dianzi University, China. He earned his B.Eng. in Thermal Energy and Power Engineering and M.Sc. in Chemistry from Shenyang University of Chemical Technology, followed by a Ph.D. in Materials Physics and Chemistry from Northeastern University. Dr. Zhang specializes in rare-earth based magnetocaloric materials, focusing on their basic research and performance optimization. He has published over 30 peer-reviewed papers, holds 6 Chinese patents, and serves on youth editorial boards. His work has advanced magnetic refrigeration technology and material science. Dr. Zhang currently leads multiple national projects and collaborates internationally to deepen understanding of magnetic properties in rare earth compounds.

Profiles

Orcid | Scopus

Education

Dr. Zhang completed his Bachelor of Engineering in Thermal Energy and Power Engineering at Shenyang University of Chemical Technology. He then pursued a Master of Science in Chemistry at the same university, graduating . Seeking deeper specialization, he earned his Ph.D. in Materials Physics and Chemistry from Northeastern University . Throughout his academic journey, Dr. Zhang developed expertise in advanced material sciences, particularly focusing on rare-earth magnetic materials. His educational background combines engineering, chemistry, and physics, providing a multidisciplinary foundation essential for his research in magnetocaloric effects. This strong academic base has supported his extensive research output and innovation in magnetic refrigeration.

Experience

Dr. Zhang currently holds the position of Assistant Researcher and Master’s supervisor at Hangzhou Dianzi University. He leads several funded projects including those supported by the National Natural Science Foundation of China and Zhejiang Provincial Universities. His research career has focused on the synthesis and characterization of rare-earth magnetocaloric materials. Dr. Zhang has developed novel compounds with significant potential for magnetic refrigeration applications. He has been actively involved in international collaborations, notably with German and Chinese research institutions, where he applied theoretical and experimental methods to study magnetic entropy and anisotropy. Additionally, he serves as a youth editorial board member for prominent journals. His experience bridges fundamental research, project leadership, and academic mentoring, making him a key figure in his research community.

 Awards and Honors

Dr. Zhenqian Zhang has been recognized for his outstanding contributions to the field of magnetic materials. His research papers have been featured as “Outstanding Papers” in leading journals such as the Journal of Physics: Energy. He holds six Chinese patents, reflecting his innovative approach to material science. Dr. Zhang’s leadership in national projects funded by the National Natural Science Foundation of China highlights his role as an emerging leader in his field. His appointment to youth editorial boards of Metallic Functional Materials and Copper Engineering journals underscores his scientific reputation and trust within the academic community. While still early in his career, Dr. Zhang’s increasing citation count and collaborative projects with international experts demonstrate growing recognition. Continued professional engagement and awards are expected as his research impact expands.

Research Focus

Dr. Zhang’s research centers on rare-earth based magnetocaloric materials, which are critical for next-generation magnetic refrigeration technologies. His work involves synthesizing novel compounds like Gd-based metal-organic frameworks (MOFs) and rare-earth intermetallics to explore their magnetic entropy and anisotropy. Using combined experimental techniques and first-principles calculations, Dr. Zhang investigates the fundamental magnetic properties that influence cooling efficiency. A key focus is tailoring sublattice structures to optimize temperature ranges for magnetic refrigeration. His interdisciplinary collaborations extend to polymer composites and semiconductor photocatalysts, broadening the application scope of magnetic materials. By pioneering new synthesis methods and theoretical analyses, Dr. Zhang aims to overcome current material limitations, providing sustainable alternatives to conventional refrigeration. His research not only advances fundamental material science but also targets environmentally friendly technologies with real-world impact.

Publications

Gd-based ferrocene complex with a large magnetocaloric effect from rapid room temperature synthesis
Authors: Xiaofei Zhang, Yuwei Wu, Shengqi An, Zhenqian Zhang
Journal: Journal of Solid State Chemistry
Year: 2025

Crystal structure, magnetic properties and cryogenic magnetocaloric performance of garnet RE3Al5O12 (RE = Tb, Dy and Ho) compounds
Authors: Zhenqian Zhang, Guangyi Sun, Xinyue Ye, Lingwei Li
Journal: Journal of Rare Earths
Year: 2025

Crystal Structure, Magnetic Property and Cryogenic Magnetocaloric Effect of Gd4Al2O9 Aluminate
Authors: Zhang Z., Na Y., Lin J., Ye X., Li L.
Journal: SSRN (also Journal of Magnetism and Magnetic Materials)
Year: 2024

Structural, magnetic and magnetocaloric properties in distorted RE2NiTiO6 double perovskite compounds
Authors: Zhenqian Zhang, Peng Xu, Youshun Jia, Lingwei Li
Journal: Journal of Physics: Energy
Year: 2023

Conclusion

Dr. Zhenqian Zhang is a promising researcher whose multidisciplinary expertise in rare-earth magnetocaloric materials significantly contributes to advancing magnetic refrigeration technology. With a strong academic background, a solid record of publications and patents, and active engagement in nationally and internationally funded projects, he demonstrates both innovative thinking and scientific rigor. His research not only deepens fundamental understanding but also holds practical potential for sustainable cooling solutions. Dr. Zhang’s growing influence, as evidenced by his editorial roles and collaborations, positions him as a valuable candidate for recognition in research excellence awards. Continued support and opportunities will likely amplify his impact in materials science and energy-efficient technologies.

Ahmed EL HAMDAOUI | Nonlinear Optical Applications | Best Researcher Award

Published on by Biophotonics Research

Dr. Ahmed EL HAMDAOUI | Nonlinear Optical Applications | Best Researcher Award

Dr. Ahmed EL HAMDAOUI | University Hassan II of Casablanca | Morocco

Dr. Ahmed EL HAMDAOUI is a researcher in Computational Materials Science and Artificial Intelligence. His expertise lies in molecular dynamics simulations and machine learning for predicting and understanding the structural, mechanical, and vibrational behavior of complex materials, especially silicate and bioactive glasses. He has authored multiple scientific publications and presented his work at major international conferences. Alongside research, he is engaged in academic instruction, teaching undergraduate physics and supervising graduate-level research projects in computational modeling and AI. He also conducts training programs in Python programming, data science, and machine learning for scientific applications. Known for his interdisciplinary approach, Dr. EL HAMDAOUI integrates physics, materials science, and artificial intelligence to develop predictive models that accelerate material design. He is also an active contributor to scientific events and community outreach, helping foster collaboration and innovation in his field. His research continues to make impactful contributions to materials informatics and computational physics.

Profile 

Orcid

Education 

Dr. Ahmed EL HAMDAOUI has a strong academic background in physics and materials science. He completed advanced studies focused on the use of molecular dynamics and machine learning for the analysis of silicate-based materials, contributing to the field of computational materials science. His master’s research involved the application of physics to archaeological dating and materials characterization, while his undergraduate work focused on the comparative performance of solar energy technologies. Throughout his academic journey, he developed a deep understanding of condensed matter physics, simulation tools, and data-driven modeling. He gained experience in handling scientific programming languages and simulation environments that are essential for modern materials research. His education has been multidisciplinary, incorporating theoretical physics, numerical simulation, and real-world applications. This strong academic foundation enables him to explore complex problems in materials science, apply machine learning to physical systems, and supervise research that bridges computational methods and experimental validation.

Experience

Dr. Ahmed EL HAMDAOUI has hands-on experience in both research and teaching within physics and materials science. His research includes the use of molecular dynamics to simulate glassy materials and machine learning techniques to predict mechanical and structural properties. He has studied vibrational anomalies, ion mobility, densification effects, and mechanical behavior in silicate, bioactive, and amorphous materials. As a research supervisor, he has guided graduate projects that explore the intersection of deep learning, molecular modeling, and material property prediction. In teaching, he delivers undergraduate physics courses such as thermodynamics, electromagnetism, and optics, and conducts practical lab sessions in mechanics, electricity, and instrumentation. Additionally, he provides professional training in Python programming and machine learning for scientific research. He also contributes to scientific events and academic outreach, serving on organizing committees and mentoring new students. His professional profile blends scientific rigor, teaching excellence, and applied computational research.

Awards and Honors

Dr. Ahmed EL HAMDAOUI has received recognition for his research contributions through invitations to present at national and international scientific conferences, workshops, and academic forums. His work on vibrational properties in glasses, mechanical property prediction using AI, and structure-property relationships in complex materials has gained visibility in the computational physics and materials science communities. He has played active roles in organizing scientific events, such as doctoral symposiums and research collaboration meetings, contributing to academic life beyond individual research. Participation in high-level international workshops on machine learning in condensed matter physics reflects his selection by leading scientific institutions. His leadership in guiding research projects and training students also reflects trust in his expertise. While his honors are not tied to specific awards, his consistent presence and contributions at influential scientific events and communities demonstrate his growing reputation and impact as a researcher and educator in computational materials science.

Research Focus

Dr. Ahmed EL HAMDAOUI focuses on computational modeling of materials using molecular dynamics simulations and artificial intelligence. His research addresses how atomic-scale structures influence macroscopic properties in glassy and amorphous materials. He explores structural anomalies such as the Boson peak, mechanical properties like Young’s modulus, and the effects of compositional changes and densification. By combining physical simulations with machine learning models, he aims to develop predictive frameworks for materials with tailored properties. His studies extend to perovskites, bioactive glasses, and ion-conducting glasses used in energy and biomedical applications. He also works on understanding ion mobility and structural evolution in multi-component glass systems. His interdisciplinary approach integrates physics, materials science, and data science to uncover hidden relationships and enable intelligent material design. The long-term goal of his research is to accelerate the development of advanced materials through simulation-driven and AI-enhanced methodologies, contributing to fields like renewable energy, nuclear safety, and materials engineering.

Publications 

The boson peak in silicate glasses: insight from molecular dynamics

  • Authors: A. El Hamdaoui, E. M. Ghard i, A. Atila, H. Jabraoui, M. Badawi, A. Hasnaoui, S. Ouaskit RSC Publishing+1

  • Journal: Physical Chemistry Chemical Physics

  • Year: 2023

Young’s Modulus of Calcium‑Alumino‑Silicate Glasses: Insight from Machine Learning

  • Authors: Mouna Sbai Idrissi, Ahmed El Hamdaoui, Tarik Chafiq OUCI

  • Journal: Journal of Marine Technology and Environment

  • Year: 2024

The impact of densification on the boson peak and structure in vitreous silica

  • Authors: Ahmed El Hamdaoui, El Mehdi Ghard i, Michael J. D. Rushton, Abdellatif Hasnaoui, Said Ouaskit Bangor University

  • Journal: Journal of the American Ceramic Society

  • Year : 2025

Conclusion

In summary, Dr. Ahmed EL is a highly capable and impactful researcher whose work bridges fundamental physics, computational modeling, and artificial intelligence. His contributions to understanding and predicting the properties of complex materials demonstrate both scientific depth and interdisciplinary innovation. With ongoing progress in high-impact publications, broader collaborations, and industry engagement, he stands as a strong and deserving candidate for the Research for Best Researcher Award.