Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

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Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

Dr. Siyao Chen , Materials Chemistry , Senior research assistant at City University of Hong Kong , Hong Kong

Dr. Siyao Chen is a Senior Research Assistant at the City University of Hong Kong, specializing in additive manufacturing and polymer-derived ceramics. With an impressive track record in advanced material research, Dr. Chen has published 11 SCI-indexed papers, including two ESI highly cited works, amassing over 610 citations. He serves as an invited editor for Frontiers in Electronics and actively contributes as a peer reviewer for prestigious journals such as Aerospace Science and Technology and the Journal of the European Ceramic Society. His research has made significant strides in 3D/4D ceramic printing, smart sensors, and semiconductor applications. In addition to academic achievements, Dr. Chen has worked on two major research projects, collaborated on four industry consultancies, and is listed as an inventor on three patents. A rising figure in materials science, Dr. Chen’s work integrates cutting-edge technology with real-world applications, contributing meaningfully to the development of intelligent ceramic systems.

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Summary of Suitability for Award:

Dr. Chen has published 11 SCI-indexed papers, including 2 ESI highly cited works, demonstrating high-impact contributions. One of these papers has gathered over 610 citations, a remarkable achievement for an early-career researcher. His work in additive manufacturing, polymer-derived ceramics, and intelligent electronics is not only innovative but also addresses complex, high-tech engineering challenges. These fields are critical in both academic and industrial applications. He serves as an invited editor for Frontiers in Electronics and is a reviewer for top-tier journals like Aerospace Science and Technology and Journal of the European Ceramic Society, indicating recognition by peers in his domain. With 3 patents, 4 consultancy projects, and 2 ongoing research projects, Dr. Chen demonstrates both academic excellence and practical application, bridging the gap between theory and industry. Dr. Siyao Chen’s research excellence, demonstrated by high-impact publications, innovation through patents, editorial and peer-review contributions, and cross-disciplinary industrial collaborations, clearly qualify him as an exceptional candidate for the “Best Researcher Award.” His academic rigor and applied innovation mark him as a rising leader in materials science and engineering research.

🎓Education:

Dr. Siyao Chen earned his doctoral degree from City University of Hong Kong, where he laid the foundation for his expertise in additive manufacturing and ceramic. His academic training emphasized interdisciplinary knowledge at the intersection of materials engineering, mechanical design, and electronic systems. During his time at CityU, Dr. Chen developed critical skills in vat photopolymerization, polymer-derived ceramic processing, and microstructural design of smart ceramics. His graduate research focused on fabricating high-performance ceramic sensors and coatings using 3D/4D printing methods. Throughout his education, he was actively involved in publishing high-impact articles and contributing to collaborative research teams. His studies not only strengthened his theoretical foundation but also fostered practical lab experience, laying the groundwork for his continued academic and industrial research. The combination of rigorous education and hands-on innovation shaped Dr. Chen’s academic identity and enabled him to push boundaries in the field of intelligent ceramic-based electronics.

🏢Work Experience:

Dr. Siyao Chen currently works as a Senior Research Assistant at the City University of Hong Kong, where he leads multiple research efforts in the field of additive manufacturing and ceramic electronics. Over the years, he has contributed to both academic and industrial projects, participating in four consultancy collaborations and leading two significant research endeavors. He has also acted as a project coordinator for the development of smart ceramic sensors, coating systems, and semiconductor devices. His work includes guiding junior researchers, managing experimental workflows, and contributing to grant applications. Dr. Chen serves as a peer reviewer for several SCI-indexed journals and as an invited editor for Frontiers in Electronics, showcasing his academic authority. His multi-disciplinary experience, spanning ceramics, polymer chemistry, and semiconductor devices, equips him to work across diverse research environments. His consistent performance and hands-on innovation have made him a valuable member of the advanced materials research community.

🏅Awards: 

Although early in his career, Dr. Siyao Chen has achieved notable recognition in his field. He is the recipient of multiple citations in high-impact journals, including two ESI Highly Cited Papers — a significant mark of influence and excellence in scholarly research. His publication in Materials Science and Engineering: R: Reports alone has gathered over 550 citations. Additionally, he was invited to join the editorial board of Frontiers in Electronics, a testament to his research integrity and subject matter expertise. His role as a reviewer for high-tier journals such as the Journal of the European Ceramic Society and Aerospace Science and Technology also highlights his academic credibility. Dr. Chen’s patent contributions and collaboration in industrial projects demonstrate the practical impact of his work. With a growing reputation in the materials science community, he is an emerging leader in ceramic additive manufacturing and intelligent electronics.

🔬Research Focus:

Dr. Chen’s primary research interests lie in additive manufacturing, polymer-derived ceramics, and semiconductor applications. He focuses on the design and processing of smart ceramic materials using 3D/4D printing technologies. His work bridges traditional ceramics with modern electronics, enabling innovations in reconfigurable structures, temperature sensors, and electromagnetic devices. A key area of interest is the development of lightweight, high-performance ceramics with tunable properties, particularly for sensing, actuation, and aerospace applications. His recent projects explore vat photopolymerization for SiCN and SiBCN-based ceramics, real-time material behavior modeling, and coating technologies for extreme environments. He is also involved in stimuli-responsive material systems, contributing to the advancement of intelligent electronics. His interdisciplinary research integrates materials engineering, electronic design, and digital fabrication, offering scalable and programmable material solutions for future smart systems. By combining structural innovation with electronic functionality, Dr. Chen aims to reshape how materials are conceived and manufactured.

Publication Top Notes:

Title: Additive manufacturing of structural materials
Citations: 572

Title: Lightweight and geometrically complex ceramics derived from 4D printed shape memory precursor with reconfigurability and programmability for sensing and actuation applications
Citations: 43

Title: Fabrication of polymer-derived SiBCN ceramic temperature sensor with excellent sensing performance
Citations: 17

Title: Fabrication of electrical semi-conductive SiCN ceramics by vat photopolymerization
Citations: 8

Title: 3D/4D additive–subtractive manufacturing of heterogeneous ceramics
Citations: 5

Title: Temperature and frequency dependent conductive behavior study on polymer-derived SiBCN ceramics
Citations: 3

Title: Novel anti-oxidation coating prepared by polymer-derived ceramic for harsh environments up to 1200°C
Citations: 2

Title: Real-time Bayesian model calibration method for C/SiC mechanical behavior considering model bias
Citations: 1

Title: Recent advances in stimuli-responsive materials for intelligent electronics

Title: Oxidation behavior of TiB2 from 600–1400°C considering microstructure evolution, oxidation kinetics, and mechanisms

Title: Evolution of dielectric properties of SiBCN ceramics and its derived wireless passive temperature sensor application

Dr. Jean Moto Ongagna | Theoretical Chemistry | Catalysis Award

Published on by Chemistry Awards

Dr. Jean Moto Ongagna | Theoretical Chemistry | Catalysis Award

Dr. Jean Moto Ongagna | Theoretical Chemistry | Lecturer – University of Douala-Cameroon , Cameroon

Dr. Jean Moto Ongagna is a Cameroonian researcher specializing in Theoretical chemistry and Computational Chemistry . He obtained his Ph.D. from the University of Douala in 2021. His expertise spans Density Functional Theory (DFT), Pharmacokinetics (ADMET), Molecular Docking, Molecular Dynamics (MD), and ab initio Molecular Dynamics (ADMP). Dr. Ongagna has contributed significantly to computational chemistry, particularly in studying metal complexes, chemical bonding, and reaction mechanisms. He has participated in prestigious international conferences and workshops, presenting groundbreaking research on chemical bonding interactions. With numerous publications in high-impact journals such as RSC Advances and the International Journal of Quantum Chemistry, his work advances the understanding of transition metal complexes and their applications. He actively collaborates with researchers worldwide and is dedicated to developing computational tools for chemical and biological systems.

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Summary of Suitability for Award:

Dr. Jean Moto Ongagna is an outstanding candidate for the “Catalysis Awards”, given his significant contributions to computational catalysis and theoretical chemistry. His research extensively applies Density Functional Theory (DFT), Quantum Chemical Calculations, and Molecular Dynamics (MD) to investigate transition metal complexes, non-standard chemical bonding, and catalytic reaction mechanisms. His studies provide deep insights into metal-ligand interactions, catalytic efficiency, and reaction pathways, which are fundamental for designing novel catalytic systems. Dr. Jean Moto Ongagna’s research in computational catalysis, transition metal chemistry, and theoretical modeling aligns perfectly with the objectives of the “Catalysis Awards”. His work advances the understanding of catalyst behavior, reaction mechanisms, and molecular interactions, making a substantial impact on modern catalysis research. His ability to integrate quantum chemistry tools with catalytic design positions him as a highly suitable candidate for this prestigious recognition.

🎓Education:

Dr. Jean Moto Ongagna pursued his higher education at the University of Douala, Cameroon. He earned a Ph.D. in Theoretical and Computational Chemistry (2021), focusing on Density Functional Theory (DFT) and molecular simulations. In 2016, he completed his Master’s degree in the same field, where he explored the computational analysis of metal-ligand interactions. His Bachelor’s degree in Physical Chemistry (2013) laid the foundation for his research on quantum chemistry and molecular modeling. Before university, he completed his GCE Advanced Level (Baccalauréat D) in 2008 at Laic Private College “La Liberté” in Douala. His education equipped him with expertise in quantum chemistry, molecular docking, and theoretical modeling, enabling him to contribute to cutting-edge research. Throughout his academic journey, he attended specialized workshops and conferences to enhance his skills in computational chemistry, continuously refining his expertise in quantum simulations and advanced chemical theories.

🏢Work Experience:

Dr. Jean Moto Ongagna has extensive experience in Theoretical chemistry and Computational Chemistry, with expertise in Density Functional Theory (DFT), Molecular Docking, Pharmacokinetics (ADMET), and ab initio Molecular Dynamics (ADMP). He has actively participated in international conferences, presenting research on transition metal complexes, chemical bonding, and molecular interactions. He has contributed to significant projects involving the computational study of catalysts, biomolecular interactions, and pharmaceutical compounds. Dr. Ongagna has also collaborated with renowned institutions and researchers worldwide, publishing extensively in high-impact journals. His research experience includes developing and applying quantum chemical tools for investigating metal-ligand interactions and reaction mechanisms. He has been involved in multiple computational chemistry workshops, enhancing his knowledge of secondary metabolite discovery, quantum topology, and electronic structure theory. His contributions have led to a deeper understanding of non-standard chemical bonding and have implications for catalysis, drug design, and materials science.

🏅Awards: 

Dr. Jean Moto Ongagna has received multiple recognitions for his contributions to Theoretical and Computational Chemistry. He has been invited as a speaker at international conferences, including the 4th Commonwealth Chemistry Posters (2023) and the Virtual Conference on Chemistry and Its Applications (2021, 2022). His research on transition metal complexes and quantum chemistry has been published in high-impact journals such as RSC Advances and the International Journal of Quantum Chemistry. He has received accolades for his computational investigations on catalytic and biomolecular systems, contributing to the advancement of quantum chemical methodologies. His participation in scientific workshops at the University of Buea (Cameroon) and Technische Universität Dresden (Germany) further highlights his academic excellence. His continuous engagement in international scientific discussions and collaborations has strengthened his reputation as a leading researcher in quantum chemistry and molecular modeling.

🔬Research Focus:

Dr. Jean Moto Ongagna’s research focuses on Theoretical and Computational Chemistry, particularly Density Functional Theory (DFT), Quantum Chemical Calculations, Molecular Docking, Pharmacokinetics (ADMET), and Molecular Dynamics (MD). He specializes in studying transition metal complexes, non-standard chemical bonds, and catalytic reactions. His work involves topological analysis of chemical interactions using advanced computational techniques such as Quantum Theory of Atoms in Molecules (QTAIM), Energy Decomposition Analysis (EDA), and Natural Bond Orbital (NBO) analysis. He has made significant contributions to understanding palladium complexes, Diels–Alder reactions, and bioactive compounds. His research extends to computational drug discovery, antimicrobial compounds, and bioinorganic chemistry, aiming to bridge the gap between theoretical modeling and experimental applications. By integrating quantum chemical methods with molecular simulations, his studies provide valuable insights into reaction mechanisms, electronic structures, and potential applications in pharmaceuticals, catalysis, and material science.

Publication Top Notes:

Deciphering the Influence of Alkylene Bridged and Chelating Mode on Pd—C and Pd—X (X = Cl, Br, and I) Bonding Interaction Within Bis‐(NHC)‐Palladium Complexes Using Quantum Chemistry Tools

Authors: Gaël Mouzong D’Ambassa, Jean Moto Ongagna, Adjieufack Abel Idrice, Désiré Bikele Mama

Year: 2024

Computational Exploration of the Impact of Low‐Spin and High‐Spin Ground State on the Chelating Ability of Dimethylglyoxime Ligand on Dihalo Transition Metal: A QTAIM, EDA, and CDA Analysis

Authors: Daniel Lissouck, Suzane Leonie Djendo Mazia, Gaël Mouzong D’Ambassa, Jean Moto Ongagna

Year: 2024

Deciphering the Influence of PdII and PdIV Oxidation States on Non-Standard Chemical Bonds Within Bis(N-Heterocyclic Carbene) Complexes: Insights from DFT

Authors: Gaël Mouzong D’Ambassa, Jean Moto Ongagna, Adjieufack Abel Idrice, Désiré Bikele Mama

Year: 2024

Exploring the Mechanism of the Intramolecular Diels–Alder Reaction of (2E,4Z,6Z)-2(allyloxy)cycloocta-2,4,6-trien-1-one Using Bonding Evolution Theory

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2023

In Vitro and In Silico Studies of Antibacterial Activities of Secofriedelane Derivatives from Senna alata (L) Roxb

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2023

How a Chromium Tricarbonyl Complex Catalyzes the [3 + 2] Cycloaddition Reaction of N-Substituted Phenylnitrones with Styrene: A Molecular Electron Density Theory Analysis

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2023

Insight into the Antioxidant and Antiradical Properties of Colorotane Sesquiterpenes Extracted from Warburgia ugandensis: Theoretical Evaluation

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2021

Topological Unraveling of the [3+2] Cycloaddition (32CA) Reaction Between N-Methylphenylnitrone and Styrene Catalyzed by the Chromium Tricarbonyl Complex Using Electron Localization Function and Catastrophe Theory

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2021

B3LYP, M06 and B3PW91 DFT Assignment of nd8 Metal-Bis-(N-Heterocyclic Carbene) Complexes

Authors: Jean Moto Ongagna, Gaël Mouzong D’Ambassa

Year: 2020