Zheng Huang | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Zheng Huang | Materials Science | Best Researcher Award

Assistant Dean from College of Pharmacy, Chongqing University of Arts and Sciences, China

Dr. Zheng Huang is an Associate Professor at the School of Pharmacy and the International Research Institute for Targeted Medicine, Chongqing University of Arts and Sciences. He specializes in the development of multifunctional nanomedicines for the treatment of cancers, focusing particularly on bioenergetic modulation and targeted delivery mechanisms. His work integrates the principles of chemical biology and pharmaceutical nanotechnology to address critical challenges such as multidrug resistance. With a research trajectory that includes a strong foundation in chemistry, advanced training in chemical biology, and academic positions that have steadily progressed from lecturer to associate professor, Dr. Huang has emerged as a prominent young scientist in the field of precision medicine. His innovative research has led to several peer-reviewed publications and a granted patent in China. In addition to being a principal investigator of a competitively funded project supported by the Chongqing Science and Technology Bureau, he actively contributes to the design and synthesis of mitochondria-targeted therapeutics. His efforts have significantly advanced cancer therapy research through novel nanoplatforms and drug delivery mechanisms. With a clear commitment to academic excellence and impactful research, Zheng Huang is a notable contributor to pharmaceutical sciences and biomedical engineering.

Professional Profile

Education

Dr. Zheng Huang pursued his academic training at Sichuan University, one of China’s top-tier research institutions. He completed his Bachelor of Science degree in Chemistry in 2013, where he gained a solid grounding in chemical principles and laboratory techniques. Building upon this foundation, he enrolled in a doctoral program in Chemical Biology at the same university and successfully earned his Ph.D. in June 2018. During his doctoral studies, Dr. Huang engaged in multidisciplinary research that bridged chemistry, biology, and medical applications, setting the stage for his future career in pharmaceutical nanotechnology. His academic training emphasized the synthesis of bioactive compounds, structure-activity relationship studies, and the development of drug delivery systems. This comprehensive education allowed him to develop the theoretical understanding and practical expertise required for innovative research in targeted therapy. The combination of a rigorous undergraduate curriculum and a research-intensive doctoral program equipped him with the skills and knowledge to tackle complex biomedical challenges. Dr. Huang’s academic background continues to influence his current research, providing a strong theoretical and experimental basis for his work on novel drug delivery platforms and cancer therapies. His educational journey has been pivotal in shaping his contributions to biomedical research.

Professional Experience

Dr. Zheng Huang has cultivated a progressive academic career at Chongqing University of Arts and Sciences, particularly within the School of Pharmacy and the International Research Institute for Targeted Medicine. He began his tenure as a Lecturer in July 2018, focusing on pharmaceutical sciences and targeted drug delivery. His appointment was extended from July 2019 to December 2023, reflecting his consistent contributions to teaching and research. In January 2024, he was promoted to the rank of Associate Professor, signifying recognition of his academic achievements and growing leadership in research. Concurrently, he has been a Postdoctoral Fellow at the Chongqing Academy of Chinese Materia Medica since November 2021, further advancing his research in traditional and modern drug systems. Across these roles, Dr. Huang has taken a proactive role in designing and executing research projects, mentoring students, and publishing influential studies. His positions reflect a consistent upward trajectory grounded in scientific rigor and academic service. His interdisciplinary affiliations have enabled him to explore advanced materials, nanotherapeutics, and drug delivery innovations. With dual roles in academia and postdoctoral research, Dr. Huang continues to bridge theoretical advancement and real-world applications, contributing meaningfully to both pharmaceutical education and translational medicine.

Research Interests

Dr. Zheng Huang’s research interests lie at the intersection of nanomedicine, targeted drug delivery, and cancer bioenergetics. He is particularly focused on the design and synthesis of multifunctional nanoplatforms capable of precisely delivering therapeutics to mitochondria within cancer cells. His investigations aim to reverse multidrug resistance through bioenergetic manipulation and redox-responsive systems. Leveraging chemical biology principles, Dr. Huang designs smart drug delivery systems that can respond to the unique microenvironment of tumors, such as elevated reactive oxygen species (ROS) levels or pH changes. His recent work includes developing CPI-613-loaded nanocarriers and co-delivery systems for chemo-photodynamic therapies. These approaches aim not only to enhance drug efficacy but also to minimize off-target toxicity and reduce side effects. Moreover, his work on combining glutathione inhibitors with mitochondria-targeted agents has opened new avenues in photodynamic therapy. Dr. Huang’s interest in structure–activity relationships, gene vectors, and non-viral delivery mechanisms also contributes to the broader field of precision medicine. His research is highly translational, addressing urgent clinical problems while innovating at the molecular level. With an emphasis on therapeutic efficiency and safety, Dr. Huang continues to explore advanced strategies for improving treatment outcomes in breast, pancreatic, and other aggressive cancers.

Research Skills

Dr. Zheng Huang possesses a comprehensive set of research skills that span synthetic chemistry, nanomaterials engineering, and biomedical application development. He is proficient in designing mitochondria-targeted drug delivery systems, with demonstrated success in creating ROS-responsive and bioenergetically active nanocarriers. His expertise includes the fabrication and characterization of nanoparticles, liposomes, and bolasomes for use in cancer therapies. Dr. Huang has strong capabilities in cell culture, fluorescence imaging, cytotoxicity assays, and mitochondrial function analysis, enabling him to evaluate the therapeutic effects of his delivery systems in vitro and in vivo. His proficiency in techniques such as dynamic light scattering (DLS), transmission electron microscopy (TEM), and UV-Vis spectroscopy allows for the precise evaluation of nanostructures and drug release kinetics. Additionally, his understanding of structure–activity relationships informs his rational design of drug molecules and carriers. Dr. Huang is experienced in drafting patents, writing scientific articles, and managing funded research projects, including grant applications and experimental design. His skill set bridges theory and practice, making him well-equipped to develop next-generation nanomedicines. By integrating chemical synthesis with biological evaluation, Dr. Huang continues to contribute meaningfully to the advancement of targeted cancer therapy technologies.

Awards and Honors

While Dr. Zheng Huang has not yet received national academic awards or fellowships, his accomplishments reflect emerging leadership in pharmaceutical nanotechnology. One of his significant achievements includes being the Principal Investigator of a competitively funded research project supported by the Chongqing Science and Technology Bureau under the Chongqing Talent Program. This three-year project, titled “Construction of a multifunctional nanodrug delivery system with controllable energy metabolism for reversing multidrug resistance,” received 100,000 RMB and is currently ongoing from October 2023 to September 2026. In addition, Dr. Huang has successfully secured a Chinese national patent (ZL202110912678.7) for a mitochondria-targeted drug based on CPI-613, highlighting his innovation in targeted cancer therapy. His authorship roles in multiple high-impact journal publications as both sole first author and sole corresponding author further signify his independent research strength and thought leadership. Although national or international honors are yet to be received, the quality and relevance of his contributions suggest strong potential for future recognition. His dedication to solving real-world medical problems through scientific innovation makes him a promising candidate for broader academic and professional accolades.

Conclusion

Dr. Zheng Huang exemplifies the qualities of an emerging leader in targeted drug delivery and pharmaceutical nanotechnology. With a rigorous academic background, progressive professional trajectory, and a growing portfolio of high-impact research, he demonstrates strong potential and scientific merit. His work on mitochondria-targeted therapies and ROS-responsive nanoplatforms addresses some of the most pressing challenges in oncology, such as drug resistance and treatment precision. As a principal investigator of a talent-funded project and the holder of a granted national patent, Dr. Huang’s innovative contributions extend from bench to potential clinical applications. While there is room for expanding his international presence and securing national-level funding such as from NSFC, his current achievements place him among the noteworthy young researchers in biomedical sciences. His publications reflect both technical excellence and relevance to critical health issues. With further support and visibility, Dr. Huang is well-positioned to make significant advances in precision medicine. Based on the evaluation of his academic profile, research outputs, and leadership in innovation, Zheng Huang is a highly suitable nominee for the Best Researcher Award, capable of contributing meaningfully to both scientific discovery and therapeutic development.

Publications Top Notes

1. Novel co‑delivery nanomedicine for photodynamic enlarged immunotherapy by cascade immune activation and efficient immunosuppression reversion

  • Year: 2024 (published Nov 1, 2024)

  • Journal: Bioorganic Chemistry (Volume 153, Article 107978)

  • Authors: Yimei Zhang, Shiyi Xiang, Yayi Wu, Can Yang, Zhongzhu Chen, Dianyong Tang, Zheng Huang

2. Multifunctional Novel Nanoplatform for Effective Synergistic Chemo‑Photodynamic Therapy of Breast Cancer by Enhancing DNA Damage and Disruptions of Its Reparation

  • Year: 2023

  • Journal: Molecules (Basel, Switzerland)

  • Authors: Zheng Huang, Tong Xian, Xiangyi Meng, Huaisong Hu, Yimei Zhang 

3. Carrier‑free nanomedicines self‑assembled from palbociclib dimers and Ce6 for enhanced combined chemo‑photodynamic therapy of breast cancer

  • Year: 2023 (first published January 9, 2023)

  • Journal: RSC Advances

  • Authors: Zheng Huang, Huaisong Hu, Tong Xian, Zhigang Xu, Dianyong Tang, Bochu Wang, Yimei Zhang

 

Juan de Pablo | Materials Science | Best Researcher Award

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Prof. Juan de Pablo | Materials Science | Best Researcher Award

Professor and Vice President from New York University, United States

Dr. Juan José de Pablo is a globally recognized leader in molecular engineering, materials science, and chemical engineering, known for his groundbreaking research and extensive leadership in academic and national scientific organizations. Currently serving as the Executive Vice President for Global Science and Technology and Executive Dean at the Tandon School of Engineering, New York University, Dr. de Pablo has had an illustrious academic and professional journey. He is also a senior scientist at Argonne National Laboratory and has held pivotal roles at the University of Chicago and the University of Wisconsin. His work spans multiple research areas, including directed self-assembly of polymers, soft materials, molecular simulation, and biotechnology. Over the years, Dr. de Pablo has established himself as a prolific researcher with over 20 patents, numerous influential publications, and editorial positions in high-impact journals. He is an elected member of prestigious institutions including the U.S. National Academy of Sciences, the National Academy of Engineering, and the American Academy of Arts and Sciences. His leadership has influenced science policy, strategic research initiatives, and interdisciplinary collaborations across the globe. His contributions are not only scientific but visionary, paving the way for future technological advances in materials design, nanotechnology, and energy solutions.

Professional Profile

Education

Dr. de Pablo’s academic foundation is as impressive as his professional accomplishments. He began his education at the National University of Mexico (UNAM), where he earned a Bachelor of Science in Chemical Engineering in 1985. His passion for chemical engineering led him to pursue a doctoral degree at the University of California, Berkeley, where he received his Ph.D. in Chemical Engineering in 1990. After completing his doctorate, he furthered his research capabilities during a postdoctoral fellowship in Materials Science at the Institute for Polymers, ETH Zurich, Switzerland, from 1990 to 1992. These formative years provided him with a robust interdisciplinary background that blends engineering principles with advanced materials science. His exposure to leading institutions in North America and Europe gave him a global perspective early in his career, which continues to shape his international collaborations and leadership roles. The rigorous training he received laid the groundwork for his expertise in thermodynamics, polymer physics, and computational modeling, which would go on to influence countless innovations in both academic and industrial domains.

Professional Experience

Dr. de Pablo’s professional career spans over three decades and includes a distinguished trajectory of teaching, research, and leadership. He began his academic career as an Assistant Professor of Chemical Engineering at the University of Wisconsin in 1992, rising through the ranks to become a full professor and eventually Director of its Materials Research Science and Engineering Center. From 2000 to 2012, he also served as Deputy Director of the Nanoscale Science and Engineering Center. In 2012, he joined the University of Chicago as the Liew Family Professor at the Institute for Molecular Engineering, and later took on pivotal roles including Co-Director of the Center for Hierarchical Materials Design (CHiMaD) and Deputy Director for Education and Outreach. Since 2018, he has also been CEO of UChicago-Argonne LLC. Dr. de Pablo’s influence extends beyond academia into national and global science leadership, particularly through his vice presidency roles related to U.S. National Laboratories and global innovation. In 2024, he was appointed Executive Dean at NYU’s Tandon School of Engineering, a role through which he continues to shape engineering education and research strategy. His extensive professional background reflects a unique combination of scientific innovation and strategic governance.

Research Interests

Dr. de Pablo’s research interests are both broad and deep, focusing on the intersection of molecular engineering, materials science, and computational physics. A primary focus of his work is on the directed self-assembly of block copolymers, a field in which he has pioneered several methodologies now used in nanomanufacturing and lithography. He also investigates thermophysical properties of soft materials, advanced polymer systems, biological interfaces, and molecular thermodynamics. His interest in computational modeling has led to the development of new simulation tools and theoretical frameworks for studying molecular and nanoscale systems, facilitating predictions of material behavior with high accuracy. Additionally, Dr. de Pablo has contributed significantly to biotechnology research, particularly in areas related to cryopreservation, stem cell engineering, and synthetic biology. His interdisciplinary approach allows him to tackle complex problems that span chemistry, physics, and engineering. Through collaborative projects and centers such as CHiMaD, he works closely with experimentalists to translate computational models into real-world applications. His research agenda reflects an enduring commitment to solving fundamental scientific challenges while also addressing practical issues in health, energy, and technology.

Research Skills

Dr. de Pablo possesses an exceptional array of research skills that reflect his training and contributions across multiple scientific disciplines. He is a world leader in computational modeling and molecular simulation, applying these techniques to study the thermodynamic and kinetic behavior of polymers, colloids, and biological systems. His skillset includes advanced knowledge of coarse-grained and multiscale simulations, free energy calculations, and structure-property prediction methods. Beyond computational proficiency, he has deep expertise in thermodynamics, statistical mechanics, and polymer physics. His laboratory and theoretical work complement each other, allowing him to bridge gaps between experimental observations and theoretical predictions. He is also adept at integrating interdisciplinary methods, including those from materials science, chemical engineering, and applied physics. His ability to conceptualize and lead large-scale research initiatives, such as the Materials Genome Initiative, highlights his strengths in research strategy and innovation management. In mentoring and supervision, Dr. de Pablo has guided dozens of Ph.D. students and postdoctoral fellows, instilling in them a rigorous and holistic research methodology. His technical versatility and collaborative mindset are key reasons behind his influential role in shaping modern materials science.

Awards and Honors

Dr. de Pablo has been the recipient of numerous prestigious awards and honors that reflect the depth, breadth, and impact of his scientific career. Early in his career, he received multiple young investigator awards from leading institutions like NSF, IBM, Xerox, 3M, and DuPont, signaling his early promise. He went on to receive the Presidential Faculty Fellow Award from President Bill Clinton and was later elected as a Fellow of the American Physical Society and the American Academy of Arts and Sciences. His research has been recognized through lectureships and invited professorships at top global institutions such as ETH Zurich, Stanford, and the University of Michigan. He has delivered keynote talks and plenary lectures at more than 30 prestigious conferences and universities worldwide. In 2016, he was elected to the U.S. National Academy of Engineering and later to the National Academy of Sciences in 2022. Internationally, he holds honors like the Marie Curie Professorship and the Chevalier de l’Ordre du Mérite (France, 2024). His accolades also include the Polymer Physics Prize from the American Physical Society and numerous distinguished lectureships from Caltech, MIT, Princeton, and others. These honors underline his status as a leading global authority in materials and molecular engineering.

Conclusion

Dr. Juan José de Pablo exemplifies excellence in scientific research, innovation, and leadership. His prolific academic career, paired with his impactful administrative and advisory roles, highlights a rare combination of deep technical expertise and visionary leadership. His contributions to molecular engineering and materials science have not only expanded fundamental scientific understanding but have also enabled new technologies in fields ranging from nanolithography to cryopreservation. With over 20 patents, numerous high-impact publications, and a strong track record of mentorship, Dr. de Pablo has influenced both the academic community and industrial applications. His election to multiple national academies and his global recognition through prestigious awards are testaments to the quality and impact of his work. While already an established authority, he continues to contribute actively through roles in science policy, research strategy, and education at the highest levels. In summary, Dr. de Pablo’s lifelong dedication to advancing science and mentoring the next generation of researchers makes him a truly deserving candidate for the Best Researcher Award. His career serves as an inspiration and a benchmark for excellence in global scientific leadership.

Publications Top Notes

  1. Water-mediated ion transport in an anion exchange membrane
    Nature Communications, 2025
    Citations: 2
  2. Structural studies of the IFNλ4 receptor complex using cryoEM enabled by protein engineering
    Nature Communications, 2025
    Citations: 1
  3. Reflection and refraction of directrons at the interface
    Proceedings of the National Academy of Sciences of the United States of America, 2025
  4. Free-Energy Landscapes and Surface Dynamics in Methane Activation on Ni(511) via Machine Learning and Enhanced Sampling
    ACS Catalysis, 2025
  5. Synthetic Active Liquid Crystals Powered by Acoustic Waves
    Advanced Materials, 2025
  6. Current Advances in Genome Modeling Across Length Scales 2025
  7. Chromatin structures from integrated AI and polymer physics model
    PLOS Computational Biology, 2025
    Citations: 1
  8. A Twist on Controlling the Equilibrium of Dynamic Thia-Michael Reactions
    Journal of Organic Chemistry, 2025
  9. Bio-Based Surfactants via Borrowing Hydrogen Catalysis
    Chemistry – A European Journal, 2025
  10. Efficient sampling of free energy landscapes with functions in Sobolev spaces
    Journal of Chemical Physics, 2025
    Citations: 1

Hanaa Abd El-Hamid | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Hanaa Abd El-Hamid | Materials Science | Best Researcher Award

Associate Professor from National Research Centre, Egypt

Hanaa Kamel Abd El-Hamid Essway is an accomplished Egyptian researcher specializing in ceramics, refractory, and building materials with extensive expertise in bioactive and sustainable materials. she currently serves as an Assistant Professor at the National Research Centre. With over 20 years of progressive experience, Dr. Essway has built a strong research portfolio focusing on the development of innovative materials for biomedical, dental, and structural applications. Her research emphasizes the use of cost-effective and eco-friendly materials, aligning her work with both scientific advancement and environmental sustainability. She has published numerous articles in highly regarded international journals such as Ceramics International, Scientific Reports, and Heliyon, covering critical areas like bio-cements, corrosion-resistant coatings, and dental restorative materials. In addition to her research, she is actively involved in training and mentoring university students and has participated in several national and international conferences. Dr. Essway possesses a strong blend of practical laboratory expertise and theoretical knowledge, and she continuously seeks to contribute to the advancement of material science. Her career reflects her dedication to scientific excellence, continuous learning, and impactful research that addresses real-world challenges.

Professional Profile

Education

Dr. Hanaa Kamel Abd El-Hamid Essway has pursued a solid academic path that firmly established her expertise in chemistry and materials science. She earned her Ph.D. in Chemistry from Ain Shams University, Egypt, in 2013. Her doctoral research, titled “Utilization of Egyptian Oil Shales in Manufacture of High-Belite Cement and Activated Pozzolanic Ash,” focused on sustainable and cost-efficient materials for construction, demonstrating her early commitment to resource-efficient technologies. Before her doctoral studies, she completed her Master’s degree in Chemistry in 2006 from Menufiya University, where she conducted in-depth studies on the use of Egyptian oil shales in cement production. Her Master’s research laid the groundwork for her doctoral investigations and subsequent career focus on eco-friendly building materials. Dr. Essway began her academic journey by earning a Bachelor’s degree in Chemistry from Menufiya University in 1999 with high distinction, graduating with an overall rating of “Very Good.” Her continuous educational progression from undergraduate studies to advanced research degrees reflects her sustained academic dedication and expertise in her field. These educational achievements have provided her with a comprehensive understanding of both theoretical chemistry and its practical applications in material development.

Professional Experience

Dr. Hanaa Kamel Abd El-Hamid Essway has demonstrated consistent career growth through her long-standing association with the National Research Centre in Egypt. She currently holds the position of Assistant Professor in the Ceramics, Refractory, and Building Materials Department, a role she has occupied since February 2023. Her academic journey within the Centre began in 2001 as a Research Assistant, and she gradually progressed through the ranks as an Assistant Researcher, Researcher, and finally Assistant Professor. Between 2006 and 2013, she served as an Assistant Researcher, where she honed her skills in developing novel materials for biomedical and structural use. Following this, she worked as a full-time Researcher until 2023, during which she made significant research contributions, particularly in the area of bio-cement and corrosion-resistant coatings. Over her career, Dr. Essway has participated in several specialized training courses, student mentorship programs, and international scientific conferences. Her professional experience not only showcases her research capabilities but also highlights her ability to apply her scientific knowledge in real-world materials development. This long-term commitment to research and education has positioned her as a highly respected expert in her field.

Research Interest

Dr. Hanaa Kamel Abd El-Hamid Essway’s research interests are deeply rooted in the development of sustainable, cost-effective, and bioactive materials for use in various industrial and biomedical applications. She is particularly focused on ceramics, bio-cement, corrosion-resistant coatings, and dental restorative materials. One of her primary areas of investigation is the utilization of locally available, low-cost materials such as Egyptian oil shales and soda-lime-silica glass in cement and bioactive composites, aiming to reduce manufacturing costs while enhancing material performance. Her work on nano-structured coatings for corrosion protection and biocompatible composites has significant potential for medical implants and dental applications. Additionally, Dr. Essway is interested in the hydration behavior and remineralization potential of modified cements, exploring how novel composites can improve the strength and longevity of dental restorations. Her cross-disciplinary research approach integrates chemistry, materials science, and biomedical engineering, contributing to both environmental sustainability and human health. Dr. Essway’s research is geared toward solving real-world challenges by improving material properties such as biocompatibility, antibacterial resistance, and mechanical durability, making her work highly relevant for industries such as healthcare, construction, and biomaterials development.

Research Skills

Dr. Hanaa Kamel Abd El-Hamid Essway possesses a diverse and advanced set of research skills that reflect her hands-on expertise in experimental design, material synthesis, and analytical characterization. She is highly skilled in developing and modifying bioactive cements, corrosion-resistant coatings, and nano-structured materials, applying polymeric methods and microwave combustion techniques for precise material fabrication. Dr. Essway’s extensive experience includes characterizing materials using advanced techniques to study microstructures, hydration behaviors, and bioactivity. She has effectively contributed to the synthesis of tricalcium silicate bio-cements, nano-alumina coatings, and zinc oxide-based composites with antibacterial and biocompatible properties. Additionally, she is proficient in evaluating the mechanical properties and corrosion resistance of coating layers, which is essential for biomedical applications. Dr. Essway is adept at using statistical tools and research methodologies for data interpretation and scientific reporting. She also has strong computer skills, particularly in Microsoft Office applications, which she uses for scientific writing and data management. Her ability to collaborate with multidisciplinary teams, conduct literature reviews, and supervise laboratory experiments further strengthens her research portfolio. Her continuous participation in training workshops and scientific conferences has allowed her to stay updated with modern research methodologies and industry practices.

Awards and Honors

While specific award titles were not listed, Dr. Hanaa Kamel Abd El-Hamid Essway’s career achievements demonstrate significant recognition within the scientific community. Her long-standing role at the National Research Centre and her progression to Assistant Professor underscore the institutional trust and recognition of her capabilities and contributions. Throughout her career, she has been actively involved in major research projects, student mentorship, and national-level training initiatives, which reflect her respected standing as both a researcher and educator. Dr. Essway has participated in several high-profile international and national conferences, where she has presented her work alongside leading experts in material science and biomaterials. Her published articles in top-tier journals such as Ceramics International, Scientific Reports, and Heliyon are further testament to the scientific community’s acknowledgment of the value and relevance of her research. Her engagement in skill development programs and training workshops, including scientific writing and occupational safety, shows her commitment to continuous improvement. The cumulative impact of her scientific contributions, teaching, and professional development indicate that she is a well-regarded figure in her field, deserving of recognition through honors such as the Best Researcher Award.

Conclusion

In conclusion, Dr. Hanaa Kamel Abd El-Hamid Essway stands out as a dedicated and accomplished researcher whose work significantly advances the fields of ceramics, bio-cement, and sustainable building materials. Her research is characterized by innovation, interdisciplinary approaches, and practical solutions that address real-world challenges in biomedical and construction applications. With more than 20 years of progressive experience, she has contributed extensively to the scientific community through impactful publications, participation in conferences, and mentorship of university students. Dr. Essway’s focus on using cost-effective and locally sourced materials aligns her work with global sustainability goals while simultaneously pushing the frontiers of material performance and safety. Her research skills, including advanced synthesis techniques, material characterization, and data analysis, have consistently yielded valuable findings that are well-recognized by international journals. Although her work would benefit from greater international collaboration and leadership roles, her proven research productivity and technical expertise make her a strong candidate for prestigious research awards. Dr. Essway’s career exemplifies the qualities of a Best Researcher Award recipient: dedication, innovation, academic excellence, and a tangible contribution to society

Publications Top Notes

1. Alkali Activation of Blended Cements Containing Oil Shale Ash

  • Authors: M.M. Radwan, L.M. Farag, S.A. Abo-El-Enein, H.K. Abd El-Hamid

  • Journal: Construction and Building Materials 40, 367-377

  • Year: 2013

  • Citations: 29

2. Preparation and Characterization of Nano-Tetracalcium Phosphate Coating on Titanium Substrate

  • Authors: M.M.R. M. Fathi, H.K. Abd El-Hamid

  • Journal: International Journal of Electrochemical Science 11, 3164-3178

  • Year: 2016

  • Citations: 17

3. Influence of Saline Solution on Hydration Behavior of β-Dicalcium Silicate in Comparison with Biphasic Calcium Phosphate/Hydroxyapatite Bio-Ceramics

  • Authors: M.M. Radwan, H.K. Abd El-Hamid, A.F. Mohamed

  • Journal: Materials Science and Engineering: C 57, 355-362

  • Year: 2015

  • Citations: 17

4. Physico-Mechanical Characteristics of Tri-Calcium Silicate Pastes as Dentin Substitute and Interface Analysis in Class II Cavities: Effect of CaCl₂ and SBF Solutions

  • Authors: M.M. Radwan, S.M. Nagi, H.K. Abd El-Hamid

  • Journal: Heliyon 5 (6)

  • Year: 2019

  • Citations: 16

5. Influence of Nano-Silica Additions on Hydration Characteristics and Cytotoxicity of Calcium Aluminate as Biomaterial

  • Authors: H.K. Abd El-Hamid, M.M. Radwan

  • Journal: Heliyon 5 (7)

  • Year: 2019

  • Citations: 13

6. Synthesis, Properties and Hydration Characteristics of Novel Nano-Size Mineral Trioxide and Tetracalcium Phosphate for Dental Applications

  • Authors: M.M. Radwan, H.K. Abd El-Hamid, S.M. Nagi

  • Journal: Oriental Journal of Chemistry 32 (5), 2459

  • Year: 2016

  • Citations: 12

7. Characterization, Bioactivity Investigation and Cytotoxicity of Borosilicate Glass/Dicalcium Silicate Composites

  • Authors: R.L.E., H.K. Abd El-Hamid, S.M. Abo-Naf

  • Journal: Journal of Non-Crystalline Solids 512, 25-32

  • Year: 2019

  • Citations: 11

8. Evaluation of Bioactivity, Biocompatibility, and Antibacterial Properties of Tricalcium Silicate Bone Cement Modified with Wollastonite/Fluorapatite Glass and Glass-Ceramic

  • Authors: H.K. Abd El-Hamid, A.M. Fayad, R.L. Elwan

  • Journal: Ceramics International 50 (14), 25322-25332

  • Year: 2024

  • Citations: 10

9. Incorporation of Strontium Borosilicate Bioactive Glass in Calcium Aluminate Biocement: Physicomechanical, Bioactivity and Antimicrobial Properties

  • Authors: H.K. Abd El-Hamid, A.A. El-Kheshen, A.M. Abdou, R.L. Elwan

  • Journal: Journal of the Mechanical Behavior of Biomedical Materials 144, 105976

  • Year: 2023

  • Citations: 8

10. Synthesis, Characterization and Antimicrobial Activity of Nano-Crystalline Tricalcium Silicate Bio-Cement

  • Authors: H.K. Abd El-Hamid, H.H. Abo-Almaged, M.M. Radwan

  • Journal: Journal of Applied Pharmaceutical Science 7 (10), 001-008

  • Year: 2017

  • Citations: 8

 

 

Tarek Naadia | Materials Science | Sustainable Engineering Leadership Award

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Dr. Tarek Naadia | Materials Science | Sustainable Engineering Leadership Award

Lecturer researcher from Polytechnic School of Architecture and Urban Planning EPAU, Algeria

Dr. NAADIA Tarek is an accomplished Associate Professor in Civil Engineering with a specialization in the mechanics and rheology of self-compacting concrete. Holding a University Habilitation awarded in 2021 from USTHB, she is a respected teacher-researcher affiliated with the Polytechnic School of Architecture and Urbanism (EPAU) and a key member of the Civil Engineering Laboratory (LBE). Her work focuses on advancing sustainable construction materials, particularly optimizing the performance and flow properties of steel fiber reinforced self-compacting concrete using innovative experimental design techniques. Dr. Tarek’s research outputs have been published in high-impact journals, emphasizing both the mechanical and rheological characteristics of eco-friendly concrete formulations incorporating industrial by-products such as tuff and marble powders. She combines rigorous scientific methodology with practical applications that support the development of greener, more durable building materials. Throughout her academic career, Dr. Tarek has demonstrated a commitment to excellence in research, teaching, and collaborative innovation within the civil engineering community. Her expertise aligns well with global efforts to promote sustainability in infrastructure development and materials science. Dr. Tarek’s contributions position her as a valuable leader in sustainable engineering research, with a growing impact on both regional and international levels.

Professional Profile

Education

Dr. NAADIA Tarek completed her highest academic qualification with a University Habilitation in Civil Engineering, awarded on January 21, 2021, at the University of Science and Technology Houari Boumediene (USTHB). This qualification represents a significant academic milestone, signifying her capability to conduct independent research, supervise doctoral students, and contribute original knowledge to her field. Her educational journey has been deeply rooted in civil engineering, with a particular focus on materials science and mechanics. Although specific earlier degrees are not listed, the habilitation level indicates advanced expertise beyond the doctoral level, underscoring her extensive research experience and academic maturity. The habilitation also reflects a comprehensive understanding of both theoretical foundations and applied techniques related to concrete rheology, material optimization, and sustainable construction technology. Her educational background equips her with the tools necessary to drive innovation in civil engineering and to influence the development of sustainable materials that address modern construction challenges. The advanced training and scholarship involved in attaining the habilitation have prepared her for a leading role in academia and research, enabling her to contribute effectively to the scientific community and to mentor future engineers.

Professional Experience

Dr. NAADIA Tarek currently serves as an Associate Professor (Class A) and a Teacher-Researcher at the Polytechnic School of Architecture and Urbanism (EPAU). She is also an active member of the Civil Engineering Laboratory (LBE) at USTHB, where she engages in research on the mechanics of materials, focusing particularly on self-compacting concrete. Her professional role involves a blend of teaching, laboratory research, and project management. As a lecturer, she contributes to civil engineering curricula, imparting knowledge on construction materials, experimental techniques, and sustainability concepts. Within the laboratory, she conducts experimental research that integrates mechanical testing and rheological measurement methods to optimize concrete formulations. Dr. Tarek’s work includes the development of new procedures for measuring concrete flow behavior and the application of design of experiments (DOE) methodologies to fine-tune mix designs for performance and environmental benefits. Her position requires collaboration with fellow researchers, students, and industry stakeholders to ensure practical relevance and innovation. Over time, she has established herself as a key figure in her department, contributing to research projects and academic advancements that enhance sustainable engineering practices in Algeria and beyond.

Research Interests

Dr. NAADIA Tarek’s primary research interests lie at the intersection of civil engineering materials, rheology, and sustainability. She specializes in the study and optimization of self-compacting concrete (SCC), focusing on both its rheological (flow) properties and mechanical performance. Her work emphasizes the development of sustainable concrete formulations that incorporate industrial by-products such as marble and tuff powders, which serve as partial replacements for traditional cement or aggregates. This approach not only improves the environmental footprint of concrete but also enhances its durability and functionality. A significant aspect of her research involves applying the design of experiments (DOE) methodology to systematically optimize the composition and performance of steel fiber reinforced self-compacting concrete (SFRSCC). This method allows for efficient exploration of multiple variables and their interactions, facilitating robust improvements in concrete quality. Dr. Tarek also investigates the rheological behavior of concrete mixtures, developing new measurement procedures to better understand their flow characteristics under various conditions. Her research contributes to sustainable construction practices by promoting materials that reduce resource consumption, waste, and energy use while improving structural integrity and longevity.

Research Skills

Dr. NAADIA Tarek possesses a comprehensive skill set tailored to experimental civil engineering research, particularly in concrete materials science. She is proficient in rheological testing methods for assessing the flow behavior of self-compacting concrete, including the design and implementation of novel measurement procedures. Her expertise extends to mechanical characterization techniques for fiber-reinforced composites, enabling detailed analysis of strength, durability, and deformation properties. She employs advanced statistical tools, notably the design of experiments (DOE) approach, to optimize material formulations systematically, which enhances research efficiency and reliability. This methodological rigor allows her to manage complex variables and interactions within concrete mix designs, leading to reproducible and scalable results. Additionally, Dr. Tarek is skilled in interpreting data to improve concrete sustainability by integrating alternative materials such as marble and tuff powders. Her laboratory experience is complemented by academic teaching, where she applies her research skills to train future engineers in experimental and analytical techniques. Collectively, these competencies support her ability to innovate within sustainable engineering and to drive research that meets both academic standards and practical industry needs.

Awards and Honors

While the CV provided does not specify particular awards or honors received by Dr. NAADIA Tarek, her attainment of the University Habilitation itself represents a prestigious academic recognition. The habilitation is a significant scholarly achievement that acknowledges her capability for independent research and academic leadership. This advanced qualification is often regarded as a benchmark of excellence within many academic systems, highlighting her contributions to civil engineering research and education. Furthermore, Dr. Tarek’s publications in high-impact journals reflect peer recognition of the quality and relevance of her work. Her growing portfolio of research articles and her position as an Associate Professor at a leading institution further attest to her professional esteem and influence within her field. For future career development, formal awards for sustainable engineering or leadership in research could complement her credentials and enhance her profile internationally. Participation in academic societies, editorial boards, or conference leadership roles may also lead to additional honors, reinforcing her position as a research leader.

Conclusion

Dr. NAADIA Tarek is a promising and dedicated civil engineering researcher with a clear focus on sustainable construction materials. Her expertise in the rheology and optimization of self-compacting concrete, combined with her use of innovative experimental design methods, positions her at the forefront of sustainable materials research. Her academic qualifications, including a University Habilitation, and her role as an Associate Professor underscore her capability for independent research and leadership within academia. Although further international collaboration and formal recognition through awards could strengthen her profile, her existing contributions demonstrate significant potential for advancing sustainable engineering practices. Dr. Tarek’s work is particularly relevant to the global imperative of reducing environmental impacts in construction, supporting the development of eco-friendly materials that are both durable and efficient. With continued research productivity and expanded engagement with the international engineering community, she is well positioned to become a leading figure in sustainable engineering research and innovation.

Publications Top Notes

  • Rheological and mechanical optimization of a steel fiber reinforced self-compacting concrete using the design of experiments method
    Authors: D Gueciouer, G Youcef, N Tarek
    Journal: European Journal of Environmental and Civil Engineering, Volume 26, Issue 3, Pages 1097-1117
    Year: 2022
    Citations: 28

  • Development of a measuring procedure of rheological behavior for self compacting concrete
    Authors: T Naadia, Y Ghernouti, D Gueciouer
    Journal: Journal of Advanced Concrete Technology, Volume 18, Issue 6, Pages 328-338
    Year: 2020
    Citations: 4

  • Rheology-compactness-granularity correlations of self-compacting concretes
    Author: T Naadia
    Year: 2014
    Citations: 1

  • Optimization of Steel Fiber-Reinforced Self-Compacting Concrete with Tuff Powder
    Authors: T Naadia, D Gueciouer
    Journal: Construction and Building Materials, Volume 474, Article 140759
    Year: 2025

  • Formulation and characterization of steel fiber reinforced self-compacting concrete (SFRSCC) based on marble powder
    Authors: T Naadia, D Gueciouer, Y Ghernouti
    Journal: Selected Scientific Paper – Journal of Civil Engineering
    Year: 2025

  • Effect of the aggregates size on the rheological behaviour of the self compacting concrete
    Authors: T Naadia, F Kharchi
    Journal: International Review of Civil Engineering (IRECE), Volume 4, Issue 2, Pages 92-97
    Year: 2013






	


	

	






	
	

		


Mohammed Ali Dheyab | Materials Science | Best Researcher Award
			

				Published on  by Shen Awards			

		
	


	

		
Dr. Mohammed Ali Dheyab | Materials Science | Best Researcher Award


Senior Lecturer from University Sains Malaysia, Malaysia


Dr. Mohammed Ali Dheyab is a distinguished researcher and academic currently serving as a Lecturer in the Medical Physics Department, School of Physics at Universiti Sains Malaysia. With a strong academic foundation and over a decade of research and teaching experience, Dr. Dheyab has established himself as an expert in the interdisciplinary fields of nanotechnology, medical imaging, and materials science. He holds a PhD in Medical Physics from Universiti Sains Malaysia, an MSc in Nanomaterials Physics from Osmania University, and a BSc in Physics from Anbar University, Iraq. Dr. Dheyab has authored and co-authored more than 50 publications indexed in Google Scholar, Scopus, and Web of Science, with over 2,300 citations and an impressive h-index of 30. His work is recognized for its innovative approaches in the synthesis of nanoparticles for medical and diagnostic applications, including cancer treatment. He also actively contributes to academic life through teaching, supervising, and organizing academic and extracurricular events. His professional presence is evident across global platforms such as Google Scholar, LinkedIn, ResearchGate, and Publons. Dr. Dheyab’s ability to merge fundamental research with practical applications positions him as a leading scholar in his field, making him a strong candidate for the Best Researcher Award.


Professional Profile



Education


Dr. Mohammed Ali Dheyab’s educational trajectory reflects a strong interdisciplinary foundation that underpins his innovative research. He earned his PhD in Medical Physics from Universiti Sains Malaysia (2017–2021), where his doctoral work focused on the development of advanced nanomaterials for biomedical applications, particularly in diagnostics and cancer therapy. Prior to that, he completed a Master of Science in Nanomaterials Physics from Osmania University, India (2014–2016), where he was introduced to the synthesis and characterization of nanoscale materials and their electronic properties. His academic journey began with a Bachelor of Science in Physics from Anbar University, Iraq (2009–2013), laying the groundwork in classical and modern physics that would later support his specialization in medical imaging and nanotechnology. His strong educational background across physics, nanomaterials, and medical sciences provides him with a unique interdisciplinary skillset. It enables him to approach complex research challenges with both theoretical knowledge and practical competence. His studies in multiple countries have further enriched his academic exposure and collaborative mindset, equipping him with international perspectives essential for global scientific engagement. Dr. Dheyab’s educational qualifications have played a critical role in shaping his successful academic and research career.


Professional Experience


Dr. Mohammed Ali Dheyab has accumulated a broad and impactful professional experience across academic and research institutions. He is currently employed as a Lecturer at the Medical Physics Department, School of Physics, Universiti Sains Malaysia (USM), where he teaches various subjects including diagnostic radiology, medical lasers, and magnetic resonance imaging. Before assuming this role, he served as a Postdoctoral Fellow at the same institution from July 2021 to 2022, contributing to research in nanomedicine and imaging technologies. Between 2017 and 2020, Dr. Dheyab was affiliated as a Research Assistant with both the School of Physics and NanoBRI Lab at INFORMM, USM, where he worked on nanoparticle synthesis, cancer photothermal therapy, and multimodality imaging probes. In 2020, he also served briefly as a Research Assistant within the School of Physics, further strengthening his technical skills and collaborative research outputs. In addition to his academic roles, Dr. Dheyab has participated in student engagement initiatives as a Kawan Ambassador for the International Mobility and Collaboration Centre (IMCC) at USM. His career trajectory showcases a balance between teaching, research, and institutional service, highlighting his adaptability and dedication to both scientific advancement and student development.


Research Interest


Dr. Mohammed Ali Dheyab’s research interests lie at the intersection of nanotechnology, materials science, and medical imaging, with a focus on real-world applications in cancer diagnosis and therapy. His core areas of investigation include the synthesis and characterization of inorganic nanoparticles, molecular and cellular nanoprobes, nanomedicine, and multimodality imaging probes. A key aspect of his work is the development of smart nanoparticles for targeted cancer treatment, utilizing properties like surface chemistry and catalytic behavior for precision medicine. He is also involved in designing photothermal therapy agents and nanozymes to enhance the eradication of cancer cells, especially breast cancer. His interest in multimodal imaging technologies bridges medical physics and materials engineering, enabling improved diagnostic tools using ultrasound, MRI, and optical techniques. Dr. Dheyab also explores the integration of nanomaterials in other domains such as food packaging and environmental sensing. His research is distinguished by a blend of innovation and applicability, aiming to solve complex biomedical problems through interdisciplinary approaches. The translation of fundamental nanoscale research into clinical and industrial settings is central to his scientific vision, positioning him at the forefront of modern medical physics and materials research.


Research Skills


Dr. Mohammed Ali Dheyab possesses an impressive portfolio of research skills that spans experimental, analytical, and computational domains. He is highly proficient in nanoparticle synthesis and surface modification techniques essential for developing functional materials for medical applications. His experience includes electron beam evaporation, sol-gel processing, and colloidal methods for producing nano-scale structures. In terms of characterization, Dr. Dheyab is skilled in a wide range of techniques including UV-Vis spectroscopy, X-ray diffraction, FTIR, SEM, and TEM, which are vital for assessing the structural, morphological, and optical properties of materials. He is also adept in medical imaging instrumentation, particularly in radiological physics, magnetic resonance imaging, and laser technology, which align with his teaching responsibilities and research in cancer diagnostics. His software skills include data analysis tools like OriginLab, Microsoft Excel, and reference management systems such as EndNote and Mendeley. Furthermore, he is familiar with DICOM imaging formats, enhancing his capabilities in clinical image processing. His strong analytical mindset, combined with excellent organizational and communication skills, allows him to manage complex experiments and collaborate across disciplines. Dr. Dheyab’s research skillset is well-suited for cutting-edge investigations in nanomedicine and medical physics.


Awards and Honors


Dr. Mohammed Ali Dheyab has garnered recognition through academic achievements and extracurricular engagement throughout his career. While formal national or international awards are not explicitly listed, his accomplishments in research productivity and scholarly impact speak volumes. With over 2,300 citations and an h-index of 30, he has effectively established his scientific reputation among peers. His selection as a Kawan Ambassador for the International Mobility and Collaboration Centre (IMCC) at Universiti Sains Malaysia highlights his commitment to student life and internationalization, serving as a cultural and sports representative. He has also received the Bronze Medallion from the Life Saving Society of Malaysia, reflecting his multifaceted capabilities beyond academia. Furthermore, his role as an organizer of the Ramadan Championship in 2021 and participation in university sports activities showcase his leadership and team-building skills. Though he has not yet been recognized with major scientific awards, his consistent publication in high-impact journals and editorial contributions position him well for future accolades. As his career advances, he is likely to receive greater formal recognition in both scientific and academic circles. His profile demonstrates a blend of academic excellence, community service, and leadership potential.


Conclusion


In conclusion, Dr. Mohammed Ali Dheyab exemplifies the qualities of an emerging academic leader and accomplished researcher. His contributions to nanomedicine, medical physics, and imaging technologies are grounded in rigorous research and supported by a solid educational foundation. With a publication record that includes over 2,300 citations and appearances in high-quality, indexed journals, he has demonstrated a significant impact in his field. Dr. Dheyab’s involvement in teaching, supervision, international collaboration, and university-level engagement illustrates his commitment to the broader academic community. While there is potential for further recognition through competitive research grants, patents, or high-profile scientific awards, his trajectory indicates continuous professional growth. He has already laid the groundwork for future leadership in both research and education. His ability to merge innovative nanotechnology with real-world biomedical applications marks him as a promising candidate for prestigious honors such as the Best Researcher Award. His interdisciplinary expertise, research productivity, and dedication to academic service make him not only a valuable asset to his institution but also a noteworthy contributor to global scientific advancement.


Publications Top Notes


    

  1. 

    Simple rapid stabilization method through citric acid modification for magnetite nanoparticles
    Authors: M.A. Dheyab, A.A. Aziz, M.S. Jameel, O.A. Noqta, P.M. Khaniabadi, B. Mehrdel
    Journal: Scientific Reports, 10(1), 10793
    Year: 2020
    Citations: 206
    

    2. 

  2. 

    Recent advances in extraction, modification, and application of chitosan in packaging industry
    Authors: N. Oladzadabbasabadi, A.M. Nafchi, F. Ariffin, M.M.J.O. Wijekoon, et al.
    Journal: Carbohydrate Polymers, 277, 118876
    Year: 2022
    Citations: 168
    

    3. 

  3. 

    Green synthesis: Proposed mechanism and factors influencing the synthesis of platinum nanoparticles
    Authors: M.S. Jameel, A.A. Aziz, M.A. Dheyab
    Journal: Green Processing and Synthesis, 9(1), 386–398
    Year: 2020
    Citations: 128
    

    4. 

  4. 

    Mycosynthesis of gold nanoparticles using the extract of Flammulina velutipes, Physalacriaceae, and their efficacy for decolorization of methylene blue
    Authors: M.A. Rabeea, M.N. Owaid, A.A. Aziz, M.S. Jameel, M.A. Dheyab
    Journal: Journal of Environmental Chemical Engineering, 8(3), 103841
    Year: 2020
    Citations: 127
    

    5. 

  5. 

    Monodisperse gold nanoparticles: A review on synthesis and their application in modern medicine
    Authors: M.A. Dheyab, A.A. Aziz, P. Moradi Khaniabadi, M.S. Jameel, et al.
    Journal: International Journal of Molecular Sciences, 23(13), 7400
    Year: 2022
    Citations: 100
    

    6. 

  6. 

    Synthesis and coating methods of biocompatible iron oxide/gold nanoparticle and nanocomposite for biomedical applications
    Authors: M.A. Dheyab, A.A. Aziz, M.S. Jameel, O.A. Noqta, B. Mehrdel
    Journal: Chinese Journal of Physics, 64, 305–325
    Year: 2020
    Citations: 98
    

    7. 

  7. 

    Gold nanoparticles-based photothermal therapy for breast cancer
    Authors: M.A. Dheyab, A.A. Aziz, P.M. Khaniabadi, M.S. Jameel, N. Oladzadabbasabadi, et al.
    Journal: Photodiagnosis and Photodynamic Therapy, 42, 103312
    Year: 2023
    Citations: 96
    

    8. 

  8. 

    Mechanisms of effective gold shell on Fe₃O₄ core nanoparticles formation using sonochemistry method
    Authors: M.A. Dheyab, A.A. Aziz, M.S. Jameel, P.M. Khaniabadi, B. Mehrdel
    Journal: Ultrasonics Sonochemistry, 64, 104865
    Year: 2020
    Citations: 92
    

    9. 

  9. 

    Mushroom-assisted synthesis of triangle gold nanoparticles using the aqueous extract of fresh Lentinula edodes (shiitake), Omphalotaceae
    Authors: M.N. Owaid, M.A. Rabeea, A.A. Aziz, M.S. Jameel, M.A. Dheyab
    Journal: Environmental Nanotechnology, Monitoring & Management, 12, 100270
    Year: 2019
    Citations: 85
    

    10. 

  10. 

    Scenario analysis of COVID-19 transmission dynamics in Malaysia with the possibility of reinfection and limited medical resources scenarios
    Authors: A.M. Salman, I. Ahmed, M.H. Mohd, M.S. Jamiluddin, M.A. Dheyab
    Journal: Computers in Biology and Medicine, 133, 104372
    Year: 2021
    Citations: 73
    

    11. 


	


	

	






	
	

		


Jaroslav Polák | Materials Science | Best Researcher Award
			

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Prof. Jaroslav Polák | Materials Science | Best Researcher Award


Researcher from Institute of Physics of Materials CAS, Czech Republic




















Prof. RNDr. Jaroslav Polák, DrSc., dr.h.c., is a globally respected scientist in the field of materials science, particularly known for his pioneering research on the mechanical properties of materials, fatigue behavior, and fracture processes. Born in 1938, Prof. Polák has dedicated over six decades to scientific research, contributing foundational theories and experimental insights that have advanced the understanding of fatigue damage in metals. He has held long-term positions at the Institute of Physics of Materials, Czech Academy of Sciences, and has collaborated internationally in Canada, Japan, Finland, and France. With over 450 publications in leading journals, two monographs, several book chapters, and an h-index of 41, his work has been cited nearly 5,000 times, ranking him among the top 1,000 most cited material scientists globally. Prof. Polák’s achievements extend beyond research; he has played a key role in mentoring young scientists, shaping research agendas, and serving on editorial boards and scientific panels. His leadership in organizing international conferences and editing special journal issues has helped shape the direction of the materials fatigue field. Prof. Polák continues to contribute as a senior scientist, maintaining a central role in advanced materials research groups and European research evaluations.


Professional Profile



Education


Prof. Polák’s educational foundation is firmly rooted in solid state physics. He completed his undergraduate studies at the Faculty of Natural Sciences, Brno, in 1961, earning the RNDr. degree. Shortly after, he pursued further specialization by joining the Institute of Solid State Physics at the Czech Academy of Sciences in Prague for one and a half years, deepening his expertise in materials science. In 1965, Prof. Polák earned his CSc. degree, equivalent to a Ph.D., with a thesis focused on mechanical properties of materials, setting the stage for his lifelong research into fatigue behavior. His academic journey continued with further advanced qualifications: in 1992, he achieved the title of Docent from Brno University of Technology, followed by a habilitation (DrSc.) from the Czech Academy of Sciences in 1993. By 1999, he was appointed Professor in Materials Engineering at Brno University of Technology. These milestones reflect a consistent, high-level academic progression that supported his development as a scientific leader. Over the years, his educational background has enabled him to bridge rigorous theoretical work with experimental research, fostering innovations that have become central to the field of materials fatigue.


Professional Experience


Prof. Polák’s professional experience is both extensive and international. He has been permanently based at the Institute of Physics of Materials, Czech Academy of Sciences, Brno, since 1963, where he led the low-cycle fatigue group from 1986 to 2012. Early in his career, he gained international exposure through a postdoctoral fellowship in Canada (1970–1971) under Dr. Z.S. Basinski, followed by visiting research and teaching positions at Tampere University of Technology, Finland, and multiple long-term collaborations with Ecole Centrale de Lille, France. Between 1994 and 2003, he undertook regular annual stays as “Professeur associé” in Lille, later becoming a member of the Scientific Board. His professional leadership also included membership in the scientific panel of the Grant Agency ČR (2005–2013) and involvement in European research evaluation projects under Horizon 2020 and RFCS. Notably, Prof. Polák has combined research with teaching for over 30 years, mentoring generations of students and researchers at Brno University of Technology. His organizational and editorial roles, such as chairing the 16th International Colloquium on Mechanical Fatigue of Metals, further emphasize his influence in shaping both scientific inquiry and the broader research community.


Research Interests


Prof. Polák’s research interests center on the mechanical behavior of materials, with particular emphasis on fatigue, cyclic plastic deformation, and fracture mechanics. His pioneering work has contributed to understanding thermal fatigue, fatigue-creep interactions, short crack kinetics, and the statistical theory of hysteresis loops. He applies a multiscale approach that integrates macroscopic mechanical testing with detailed microstructural analysis, using advanced techniques to study surface relief formation, crack initiation, and damage evolution. Prof. Polák is particularly interested in high-temperature and thermomechanical fatigue processes, developing models that have practical applications in predicting material lifespan under complex loading conditions. His innovative research has informed both theoretical frameworks and experimental methodologies, bridging the gap between fundamental science and engineering practice. His current involvement with CEITEC advanced material groups reflects his continuous engagement with cutting-edge research on next-generation materials. Additionally, his work increasingly connects with computational and computer-controlled testing methods, ensuring his research remains relevant in an era where materials science is intersecting with informatics and automation.


Research Skills


Prof. Polák brings a robust set of research skills to the field of materials science, particularly in experimental design, advanced mechanical testing, multiscale material characterization, and damage mechanism analysis. His expertise includes designing and conducting low-cycle and high-cycle fatigue experiments, implementing computer-controlled testing systems, and developing predictive models for fatigue life and crack initiation. He is highly skilled in correlating microstructural features with macroscopic mechanical behavior, using techniques such as microscopy, surface relief analysis, and fracture surface examination to understand material failure processes. His background in solid state physics equips him with a deep theoretical understanding, allowing him to derive quantitative models from experimental data, such as his work on the kinetics of short cracks and the evolution of surface structures during fatigue. Furthermore, Prof. Polák’s research management and leadership skills are well established, enabling him to coordinate large-scale collaborative projects, organize international conferences, and mentor junior researchers. His ability to combine theoretical, experimental, and organizational expertise makes him a uniquely well-rounded scientific leader in the field.


Awards and Honors


Prof. Polák’s distinguished career has been recognized through numerous awards and honors, reflecting both his scientific excellence and his service to the global research community. One of his most prestigious honors is the Ernst Mach Honorary Medal for Merit in Physical Sciences, awarded by the Academy of Sciences in 2016, acknowledging his groundbreaking contributions to materials science and fatigue research. His international reputation is further underscored by the honorary doctorate (dr. h.c.) awarded by Ecole Centrale de Lille in 2004, where he also served on the Scientific Board between 2000 and 2003. Prof. Polák has been invited to deliver lectures at top institutions worldwide, including Japan, France, Canada, and Finland, and has frequently served as an invited speaker at international conferences. He chaired the Scientific and Organizing Committees of the 16th International Colloquium on Mechanical Fatigue of Metals, reinforcing his leadership standing. More recently, his expertise has been sought as an evaluator for European research projects under Horizon 2020 and RFCS. Collectively, these recognitions affirm his enduring influence and the high esteem in which he is held by the international scientific community.


Conclusion


Prof. Jaroslav Polák stands out as an extraordinary figure in the global materials science community. His six-decade career has yielded transformative insights into fatigue behavior, cyclic plasticity, and material failure mechanisms, underpinned by rigorous experimental research and innovative theoretical modeling. His contributions extend beyond scientific publications to include leadership in major international collaborations, organization of key scientific conferences, editorial work, and the mentorship of numerous young scientists. Prof. Polák’s impressive record of over 450 publications, thousands of citations, and top rankings among material science researchers underscores his profound and lasting impact. Honors such as the Ernst Mach Medal and honorary doctorate from Ecole Centrale de Lille further validate his status as a leading researcher. While his focus has traditionally been on fundamental aspects of materials behavior, he remains well-positioned to contribute to emerging interdisciplinary and computationally driven areas. Prof. Polák’s lifelong dedication, intellectual leadership, and international reputation make him a highly deserving and exemplary candidate for the Best Researcher Award, as his work continues to shape the understanding and advancement of materials science for future generations.












Publications Top Notes


    

  1. 

    Title: Dislocation Structure Near the Intergranular Fracture Surface of Cyclically Strained Polycrystalline Copper
    Authors: Polák, Jaroslav; Poczklán, Ladislav; Vražina, Tomáš
    Journal: Fatigue & Fracture of Engineering Materials & Structures
    Year: 2025
    

    2. 

  2. 

    Title: Microstructure and dislocation arrangements in Sanicro 25 steel fatigued at ambient and elevated temperatures
    Authors: Heczko, Milan; Polák, Jaroslav; Kruml, Tomáš
    Journal: Materials Science and Engineering A
    Year: 2017
    Citations: 54
    

    3. 

  3. 

    Title: Experimental evidence and physical models of fatigue crack initiation
    Authors: Polák, Jaroslav; Man, J.
    Journal: International Journal of Fatigue
    Year: 2016
    Citations: 53
    

    4. 

  4. 

    Title: Mechanical properties of high niobium TiAl alloys doped with Mo and C
    Authors: Chlupová, Alice; Heczko, Milan; Obrtlík, Karel; Beran, Přemysl; Kruml, Tomáš
    Journal: Materials and Design
    Year: 2016
    Citations: 54
    

    5. 

  5. 

    Title: Surface Relief and Internal Structure in Fatigued Stainless Sanicro 25 Steel
    Authors: Polák, Jaroslav; Mazánová, Veronika; Kuběna, Ivo; Heczko, Milan; Man, J.
    Journal: Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science
    Year: 2016
    Citations: 24
    

    6. 

  6. 

    Title: Surface profile evolution and fatigue crack initiation in Sanicro 25 steel at room temperature
    Authors: Polák, Jaroslav; Petráš, Roman; Chai, Guocai; Škorík, Viktor
    Journal: Materials Science and Engineering A
    Year: 2016
    Citations: 21
    

    7. 

  7. 

    Title: Behaviour of ODS Steels in Cyclic Loading
    Authors: Kuběna, Ivo; Kruml, Tomáš; Polák, Jaroslav
    Journal: Transactions of the Indian Institute of Metals
    Year: 2016
    Citations: 3
    

    8. 

  8. 

    Title: Basic Mechanisms Leading to Fatigue Failure of Structural Materials
    Authors: Polák, Jaroslav; Petráš, Roman; Mazánová, Veronika
    Journal: Transactions of the Indian Institute of Metals
    Year: 2016
    Citations: 8
    

    9. 

  9. 

    Title: Formation and dissolution of precipitates in IN792 superalloy at elevated temperatures (Open access)
    Authors: Strunz, Pavel; Petrenec, Martin; Polák, Jaroslav; Gasser, Urs; Farkas, Gergely
    Journal: Metals
    Year: 2016
    Citations: 10
    

    10. 

  10. 

    Title: Thermomechanical fatigue and damage mechanisms in Sanicro 25 steel
    Authors: Petráš, Roman; Škorík, Viktor; Polák, Jaroslav
    Journal: Materials Science and Engineering A
    Year: 2016
    Citations: 51
    

    11. 





















	


	

	






	
	

		


Hadi Hijazi | Materials Science | Best Researcher Award
			

				Published on  by Shen Awards			

		
	


	

		
Dr. Hadi Hijazi | Materials Science | Best Researcher Award


R&D engineer from CEA LETI, France


















Dr. Hadi Hijazi is a postdoctoral researcher specializing in microelectronics and semiconductor nanostructures, with extensive experience in epitaxial growth and device fabrication. Based in Grenoble, France, he has developed a strong academic and research background through work at top-tier institutions such as CEA-LETI, CNRS/LTM, and Saint Petersburg State University. His research encompasses the design, modeling, and experimental development of III-V materials and nanostructures for high-performance optoelectronic devices, including visible and near-infrared LEDs. His doctoral studies focused on the epitaxial growth of GaAs nanowires via HVPE and the investigation of spin and charge transport. Dr. Hijazi possesses deep technical expertise in MOCVD, HVPE, and cleanroom operations, supported by his proficiency in a wide range of characterization tools such as XRD, SEM, AFM, PL, and Raman spectroscopy. In addition to his laboratory capabilities, he is skilled in modeling and simulation using tools like Matlab, Nextnano, and Mathematica. Multilingual and collaborative, Dr. Hijazi has a history of successful international projects, combining both theoretical insight and experimental innovation. His contributions to the field are reflected in quality publications in peer-reviewed journals, and he maintains active connections with research leaders and institutions in France and abroad. He is currently an R&D engineer at CEA LETI, contributing to hybrid bonding technologies.


Professional Profile



Education


Dr. Hadi Hijazi holds a Ph.D. in Physics of Materials from Institut Pascal at Université Clermont Auvergne, France, where he worked on the development of GaAs nanowires grown on Si substrates using hydride vapor phase epitaxy (HVPE). His research addressed charge and spin diffusion in nanowires, integrating fundamental physics with advanced material synthesis techniques. Prior to his doctoral studies, Dr. Hijazi completed a Master’s degree (M2) in Nanoelectronics and Nanotechnology from Université Grenoble Alpes, where he received training in nanoscale materials, semiconductor physics, and cleanroom-based device fabrication. He also holds a Master 1 in Fundamental Physics and Nanoscience from Université Joseph Fourier in Grenoble, which laid the foundation for his later specialization in materials and device engineering. His academic training has been interdisciplinary, with strong emphasis on physics, nanotechnology, materials science, and applied electronics. His formal education has equipped him with theoretical depth and practical skill sets, enabling his contributions to multidisciplinary research involving physical modeling, simulation, and experimental validation of micro- and nanoscale structures. These qualifications have prepared him well for complex problem-solving in research-intensive environments, particularly within the highly competitive field of semiconductor materials and microelectronics.


Professional Experience


Dr. Hadi Hijazi has accumulated a robust portfolio of research and development experience across premier academic and industrial research institutions. Since July 2023, he has been serving as an R&D Engineer at CEA LETI in Grenoble, where he works on hybrid bonding technologies, a critical area for 3D integration in microelectronics. From October 2021 to June 2023, he served as a postdoctoral researcher jointly at CEA-LETI and CNRS/LTM, contributing to the IRT Nanoelec project. During this tenure, he focused on the design and simulation of novel heterostructures using III-(As,P) materials for high-performance visible and NIR LEDs. His work included epitaxial process development (MOCVD) on 300 mm substrates and comprehensive characterization of material and device properties. Prior to this, he was a postdoctoral researcher at ITMO University and Saint Petersburg State University in Russia, focusing on growth modeling of III-V and IV-IV micro/nanostructures. Dr. Hijazi also undertook an industrial internship at CEA LETI in 2016, studying the bonding of refractory metal thin films for 3D technologies. Throughout his career, he has demonstrated the ability to integrate theory, simulation, and fabrication in practical research, aligning well with multidisciplinary goals in microelectronics and optoelectronics innovation.


Research Interests


Dr. Hadi Hijazi’s research interests center around advanced semiconductor materials and their integration into high-performance optoelectronic and microelectronic devices. He is particularly focused on the design, epitaxial growth, and characterization of III-V compound semiconductors on silicon substrates, with the goal of enabling new generations of energy-efficient light sources and integrated photonics. His doctoral work involved HVPE growth of GaAs nanowires on Si(111) substrates, aiming to understand charge and spin transport mechanisms at the nanoscale. His postdoctoral research extended to MOCVD-based fabrication of InGaAs and InP heterostructures for LED applications and included structural and electro-optical characterization. He is also interested in hybrid bonding technologies and 3D integration techniques critical to the future of chip stacking and packaging. Dr. Hijazi combines experimental efforts with simulation and modeling, employing tools like Matlab and Nextnano to optimize nanostructure design and predict growth behavior. He is deeply engaged in the physical understanding of epitaxy, surface/interface interactions, and defect formation. These interests place him at the intersection of materials physics, nanotechnology, and applied engineering, with relevance to optoelectronics, spintronics, and next-generation semiconductor device platforms.


Research Skills


Dr. Hadi Hijazi possesses a comprehensive set of research skills that span theoretical modeling, experimental techniques, and process development in nanotechnology and materials science. His expertise in vapor phase epitaxy, including both MOCVD and HVPE methods, allows him to develop high-quality III-V semiconductor nanostructures on various substrates. He has extensive cleanroom experience and is adept in device fabrication processes, material growth protocols, and post-growth characterization. He is proficient in a range of analytical tools such as XRD, AFM, SEM, Raman spectroscopy, photoluminescence (PL), and electrochemical and C-V measurements. Dr. Hijazi is also skilled in simulation and modeling, using software like Matlab, Mathematica, Nextnano, Python, and C++ to analyze material behaviors and guide experimental design. His strong command of semiconductor physics and nanostructure dynamics supports both fundamental research and practical application development. He is an effective communicator in French, English, and Arabic, and his collaborative approach to research is evident in his successful engagements with multidisciplinary teams across France and Russia. Additionally, his organizational and documentation skills are well-developed, contributing to his ability to manage complex research tasks and publish high-quality scientific articles.


Awards and Honors


While specific named awards are not listed in the available information, Dr. Hadi Hijazi’s inclusion in competitive research programs and positions at prestigious institutions such as CEA-LETI, CNRS, and ITMO University itself serves as recognition of his capabilities and achievements. His acceptance into highly selective doctoral and postdoctoral programs in France and Russia, coupled with his contributions to projects such as IRT Nanoelec, suggests a high degree of merit and recognition by the scientific community. His publications in internationally recognized journals such as Nanotechnology and Journal of Physical Chemistry C also indicate the quality and impact of his research. Furthermore, his involvement in international collaborations and multidisciplinary research teams demonstrates the professional trust placed in his expertise and reliability. His continuing employment at CEA LETI in a research and development role is itself a form of institutional endorsement, affirming his value in the innovation ecosystem of advanced microelectronics. With further dissemination of his work and engagement in academic presentations or grant-funded leadership, it is likely he will accrue formal honors and awards in the near future.


Conclusion


Dr. Hadi Hijazi is an accomplished early-career researcher with strong potential for further growth in the field of semiconductor nanotechnology and microelectronics. His academic training and international research experience have equipped him with both depth and versatility, enabling contributions to next-generation devices through innovations in epitaxial growth, material design, and device integration. His ability to bridge theoretical modeling with experimental realization is a key asset, particularly in collaborative research environments. While his current achievements position him as a valuable team member and emerging expert, more visible research leadership, independent project development, and broader dissemination of research outputs could further strengthen his candidacy for major research awards. At present, Dr. Hijazi would be an ideal candidate for recognitions aimed at emerging scientists or rising researchers, and with continued productivity and impact, he is well-poised to become a leading figure in semiconductor device research. His technical expertise, commitment to quality, and collaborative ethos make him a noteworthy contributor to academic and industrial R&D. As he continues his career at CEA LETI and beyond, further contributions in both applied technologies and fundamental science can be expected.


Publications Top Notes


    

  1. Fine Pitch Superconducting Interconnects Obtained with Nb–Nb Direct Bonding
    2. 



    

  • 

    Authors: Candice M. Thomas, Pablo Renaud, Meriem Guergour, Edouard Deschaseaux, Christophe Dubarry, Jennifer Guillaume, Elisa Vermande, Alain Campo, Frank Fournel, Hadi Hijazi, Anne-Marie Papon, Catherine Pellissier, Jean Charbonnier
    

    • 

  • 

    Publication Year: 2025
    

    • 



2. Is NaOH Beneficial to Low Temperature Hybrid Bonding Integration?


    

  • 

    Authors: Hadi Hijazi¹, Paul Noël¹, Samuel Tardif², Karine Abadie¹, Christophe Morales¹, Frank Fournel¹
    

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  • 

    Publication Date: October 30, 2024
    

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Tan Wang | Materials Science | Best Researcher Award
			

				Published on  by Shen Awards			

		
	


	

		
Dr. Tan Wang | Materials Science | Best Researcher Award


Assistant Researcher from Qingdao Institute of Bio Energy and Bioprocess Technology Chinese Academy of Sciences, China




















Wang Tan is an assistant researcher at the Qingdao Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Sciences. His expertise lies in organic photovoltaic materials and solar energy conversion. With a solid academic background in energy chemistry, he has contributed to high-impact research in polymer donor materials for solar cells. His work has been published in prestigious journals, highlighting his role in advancing renewable energy technologies. He has also secured funding for independent research projects, demonstrating his growing leadership in the field. His contributions extend beyond publications to patents, indicating a strong focus on practical applications.


Professional Profile



Education


Wang Tan obtained his Ph.D. in Energy Chemistry from Xiamen University (2015-2020), where he specialized in photovoltaic materials and device performance. He also earned a bachelor’s degree in Chemistry from Xiamen University (2011-2015), providing him with a strong foundation in material science. His postdoctoral research was conducted at Shanghai Jiao Tong University (2020-2022) and the Qingdao Institute of Bioenergy and Bioprocess Technology, CAS (2022-2024), where he further explored organic solar cells and material synthesis.


Professional Experience


Since January 2025, Wang Tan has been an assistant researcher at the Qingdao Institute of Bioenergy and Bioprocess Technology, working in the Key Laboratory of Solar Photovoltaic Conversion and Utilization. His postdoctoral experience includes research at Shanghai Jiao Tong University (2020-2022) and the Qingdao Institute of Bioenergy and Bioprocess Technology (2022-2024). Throughout his career, he has focused on the design and synthesis of novel organic materials for solar energy applications. His experience extends to leading research projects and collaborating with interdisciplinary teams on high-efficiency photovoltaic materials.


Research Interests


Wang Tan’s research interests primarily focus on organic photovoltaic materials, solar energy conversion, and high-efficiency polymer donor materials. He is particularly interested in developing novel organic semiconductors for next-generation solar cells. His work explores molecular design strategies for enhancing the power conversion efficiency and stability of organic solar cells. Additionally, he investigates charge transfer mechanisms and optoelectronic properties of new photovoltaic materials to improve device performance. His research aims to bridge the gap between fundamental material science and practical applications in renewable energy technologies.


Research Skills


Wang Tan has expertise in the design and synthesis of organic photovoltaic materials, including deep-energy-level donor materials. He is skilled in various characterization techniques such as steady-state and transient fluorescence spectroscopy, electrochemical analysis, and charge transfer studies. His proficiency extends to device fabrication and performance evaluation of organic solar cells. Additionally, he has experience in computational modeling to study molecular interactions and charge dynamics in photovoltaic materials. His multidisciplinary skill set enables him to contribute to both theoretical and experimental advancements in organic solar energy research.


Awards and Honors


Wang Tan has received funding from the Shandong Natural Science Foundation (2023-2026) and the Qingdao Postdoctoral Funding Program (2022-2024) for his work on high-performance organic photovoltaic materials. He has co-authored publications in top-tier journals such as Science Bulletin and Nano Energy, showcasing his research impact. He has also been granted patents for novel polymer materials and conductive nanoparticles in solar energy applications. His contributions to organic solar cell development have been recognized within the scientific community through conference presentations and invited talks.


Conclusion


Wang Tan is a dedicated researcher in the field of organic photovoltaic materials and solar energy conversion. His academic background, research experience, and technical skills position him as a valuable contributor to renewable energy advancements. While he has made significant strides in securing funding and publishing influential research, he has the potential to further establish himself as an independent research leader. Strengthening his role as a principal investigator and securing national-level grants could enhance his impact in the field. His combination of innovation, technical expertise, and research productivity makes him a promising candidate for future advancements in organic solar energy technologies.


Publications Top Notes


    

  • HOF-Enabled Synthesis of Porous PEDOT as an Improved Electrode Material for Supercapacitor
    Authors: Z. Zhong, Zihan; Q. Shao, Qingqing; B. Ni, Baoxin; A.K. Cheetham, Anthony Kevin; T. Wang, Tiesheng
    Year: 2025
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Jian-gang Guo | Materials Science | Best Researcher Award
			

				Published on  by Shen Awards			

		
	


	

		
Prof. Dr. Jian-gang Guo | Materials Science | Best Researcher Award


Professor at Institute of Physics Chinese Academy of Sciences: Chinese Academy of Sciences Institute of Physics, China










Jian-gang Guo is a renowned physicist specializing in condensed matter physics, particularly in superconductivity and magnetic materials. He is a Full Professor at the Institute of Physics, Chinese Academy of Sciences (IOP, CAS). His research has significantly contributed to understanding strongly electron-correlated systems, with a focus on superconducting materials. One of his most notable achievements is the discovery of KxFe2Se2 high-temperature superconductors, which opened a new research field and gained worldwide recognition. He has published 118 papers in prestigious journals such as Nature, Nature Chemistry, Nature Communications, and Physical Review Letters. His work has had a profound impact on materials science and has inspired extensive global research. Additionally, he has successfully developed cubic silicon carbide (SiC) single crystals applicable for mass production. His contributions have earned him several prestigious awards, including the Second Prize of the State Natural Science Award of China. With international experience from institutions such as Rice University and the Tokyo Institute of Technology, he has established himself as a leader in superconductivity research. His innovative discoveries, extensive publication record, and international collaborations position him as a highly influential figure in modern condensed matter physics.


Professional Profile



Education


Jian-gang Guo has an extensive academic background in condensed matter and solid-state physics. He earned his Ph.D. in Condensed Matter Physics from the Institute of Physics, Chinese Academy of Sciences (IOP, CAS) in 2011. His doctoral research focused on the properties of electron-correlated materials, particularly superconductors. Prior to his Ph.D., he completed an M.S. in Condensed Matter Physics in 2008 at the State Key Laboratory of Superhard Materials, Jilin University, China. During his master’s studies, he gained expertise in high-pressure physics and material synthesis techniques. He obtained his B.S. in Solid-State Physics from the Department of Physics, Jilin University, in 2005. His undergraduate studies laid the foundation for his later work in electronic materials and crystallography. Throughout his academic journey, he has developed a strong theoretical and experimental background in superconductivity, transport properties, and magnetic interactions. His education at top institutions in China provided him with a solid platform to contribute significantly to the field of condensed matter physics. His ability to integrate fundamental physics with experimental discoveries has made him a key figure in the study of superconducting and magnetic materials.


Professional Experience


Jian-gang Guo has held several prominent academic and research positions in leading institutions worldwide. He is currently a Full Professor at the Institute of Physics, Chinese Academy of Sciences (IOP, CAS), a position he has held since September 2020. Before that, he was an Associate Professor at IOP, CAS, from 2016 to 2020, contributing to advancements in superconductivity and quantum materials. From 2014 to 2016, he was an ICAM Postdoctoral Fellow at the Department of Physics & Astronomy at Rice University, working in Prof. Pengcheng Dai’s group on neutron diffraction studies of magnetic materials. Between 2011 and 2014, he worked as a Postdoctoral Researcher at the Frontier Research Center, Tokyo Institute of Technology, under Prof. Hideo Hosono, where he expanded his expertise in novel superconducting materials. His career has been marked by international collaborations, interdisciplinary research, and groundbreaking discoveries in the field of condensed matter physics. His professional experience has allowed him to develop a strong research network and contribute significantly to both experimental and theoretical advancements in strongly correlated electronic systems.


Research Interests


Jian-gang Guo’s research primarily focuses on the physical properties of strongly electron-correlated systems, including superconductors and magnetic materials. His work involves techniques such as x-ray and neutron diffraction, low-temperature transport measurements, and theoretical modeling. He is particularly interested in exploring the relationship between crystallographic structures and electronic properties in new functional materials. One of his most significant contributions is the discovery of KxFe2Se2 high-temperature superconductors, which led to the development of a new class of alkali-metal intercalated FeSe superconductors. His research has also extended to the growth of bulk cubic silicon carbide (SiC) single crystals using high-temperature solution methods, making them suitable for industrial applications. His interests further include studying charge density waves, metal-insulator transitions, and novel quantum materials. By combining experimental and theoretical approaches, he aims to develop new materials with unique electronic and magnetic properties. His work continues to drive advancements in fundamental physics while also providing potential applications in energy storage, quantum computing, and semiconductor industries.


Research Skills


Jian-gang Guo possesses a diverse set of research skills that enable him to make significant contributions to condensed matter physics. His expertise includes x-ray and neutron diffraction techniques, which he utilizes to investigate the structural and electronic properties of superconductors and magnetic materials. He is skilled in low-temperature transport measurements, allowing him to analyze the electrical and thermal behavior of materials under extreme conditions. His experience in growing high-quality single crystals, including superconducting and semiconducting materials, has been instrumental in developing new materials for both fundamental and applied research. Additionally, he has a strong background in theoretical calculations, enabling him to model electronic structures and magnetic interactions in complex systems. His ability to integrate experimental and computational methods has allowed him to uncover new physical phenomena in strongly correlated materials. Furthermore, his experience with high-pressure synthesis techniques has contributed to the discovery of novel superconducting and magnetic materials. His research skills have been critical in advancing knowledge in condensed matter physics and developing materials with real-world applications.


Awards and Honors


Jian-gang Guo has received several prestigious awards in recognition of his outstanding contributions to condensed matter physics. In 2020, he was awarded the Second Prize of the State Natural Science Award of the People’s Republic of China, one of the highest honors for scientific research in the country. This award recognized his pioneering work on alkali-metal intercalated FeSe superconductors. In 2022, he received the Second Prize of the Beijing Municipal Natural Science Prize, highlighting his impact on superconductivity research. Additionally, he was honored with the CAS Science and Technology Promotion Development Award in 2021 for his contributions to material synthesis and characterization. His research has been widely acknowledged, with his work on high-temperature superconductors being selected as a Milestone Paper for the 50th Anniversary of Physical Review B. These accolades reflect his significant influence on the scientific community and his role in advancing the understanding of strongly correlated electron systems. His continued contributions to superconductivity and novel materials research further solidify his reputation as a leading figure in his field.


Conclusion


Jian-gang Guo is a distinguished researcher whose work has had a transformative impact on condensed matter physics. His discovery of KxFe2Se2 high-temperature superconductors has influenced global research, inspiring over 300 teams worldwide. With 118 publications in top-tier journals and numerous prestigious awards, he has established himself as a leader in superconductivity and materials science. His ability to integrate experimental and theoretical approaches has led to the discovery of novel quantum materials and superconducting compounds. His contributions extend beyond fundamental research, as demonstrated by his work on silicon carbide single crystals, which have industrial applications. His extensive international collaborations, research skills, and ability to mentor young scientists further strengthen his profile. While his work has already made significant contributions to physics, expanding interdisciplinary research into quantum computing, energy materials, and industrial partnerships could further enhance his influence. His achievements, dedication, and pioneering discoveries make him a strong candidate for the Best Researcher Award. His continued research is expected to shape the future of superconductivity, quantum materials, and electronic devices for years to come.


Publications Top Notes


    

  1. 

    Modeling and Suppressing Interfacial Instability in Growth of SiC from High-Temperature Solutions
    

      

    • Authors: Sheng Da, Wang Guobin, Yang Yunfan, Wang Wenjun, Chen Xiaolong
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    • Year: 2025
      • 

    

    2. 

  2. 

    Size-Effect Enriched Phase Diagram in p-Type Skutterudite Superconductor Ir₃.₈Sb₁₂
    

      

    • Authors: Wang Junjie, Liu Xu, Pei Cuiying, Guo Jianggang, Ying Tianping
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    • Year: 2025
      • 

    

    3. 

  3. 

    Intermediately Coupled Type-II Superconductivity in a La-Based Kagome Metal La₃Al
    

      

    • Authors: Yu Yingpeng, Liu Zhaolong, Chen Zhaoxu, Guo Jianggang, Jin Shifeng
      • 

    • Year: 2025
      • 

    • Citations: 1
      • 

    

    4. 

  4. 

    Dynamic-to-Static Switch of Hydrogen Bonds Induces a Metal–Insulator Transition in an Organic–Inorganic Superlattice
    

      

    • Authors: Xie Zhenkai, Luo Rui, Ying Tianping, Guo Jianggang, Chen Xiaolong
      • 

    • Year: 2024
      • 

    • Citations: 6
      • 

    

    5. 

  5. 

    Antiferromagnetic Frustration Behavior with Face-Sharing CuAs₄ Tetrahedrons in Conducting ACu₆As₃ (A = Li and Na)
    

      

    • Authors: Yang Yuxin, Chen Zhaoxu, Liu Xu, Chen Xu, Guo Jianggang
      • 

    • Year: 2024
      • 

    

    6. 

  6. 

    Evidence of a Hydrated Mineral Enriched in Water and Ammonium Molecules in the Chang’e-5 Lunar Sample
    

      

    • Authors: Jin Shifeng, Hao Munan, Guo Zhongnan, Guo Jianggang, Chen Xiaolong
      • 

    • Year: 2024
      • 

    • Citations: 6
      • 

    

    7. 

  7. 

    Quantum-Confined Tunable Ferromagnetism on the Surface of a Van der Waals Antiferromagnet NaCrTe₂
    

      

    • Authors: Li Yidian, Du Xian, Wang Junjie, Chen Yulin, Yang Lexian
      • 

    • Year: 2024
      • 

    

    8. 

  8. 

    Superconductivity in Pressurized Trilayer La₄Ni₃O₁₀−δ Single Crystals
    

      

    • Authors: Zhu Yinghao, Peng Di, Zhang Enkang, Guo Jianggang, Zhao Jun
      • 

    • Year: 2024
      • 

    • Citations: 41
      • 

    

    9. 

  9. 

    Influence of Dimensionality on Superconductivity in Pressurized 3D SnPSe₃ Single Crystal
    

      

    • Authors: Wang Junjie, Liu Xu, Zhang Ling, Guo Jianggang, Ying Tianping
      • 

    • Year: 2024
      • 

    

    10. 

  10. 

    High-Quality and Wafer-Scale Cubic Silicon Carbide Single Crystals
    

    11. 



    

  • Authors: Wang Guobin, Sheng Da, Yang Yunfan, Guo Jianggang, Chen Xiaolong
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  • Year: 2024
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  • Citations: 10
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Gregorio Gonzalez | Materials Science | Best Researcher Award
			

				Published on  by Shen Awards			

		
	


	

		
Assoc. Prof. Dr. Gregorio Gonzalez | Materials Science | Best Researcher Award


Associate Professor at ITSM, Mexico










Dr. Gregorio Gonzalez Zamarripa is an accomplished researcher and Associate Professor at Tecnológico Nacional de México, Instituto Tecnológico Superior de Monclova. With a PhD in Materials Science from Saltillo Institute of Technology (2011), he specializes in hydrometallurgy, waste recovery, and advanced material processing. His career spans over 46 years in basic sciences and engineering, focusing on metal recovery from industrial by-products and developing innovative environmental solutions. Dr. Zamarripa is a member of the National System of Researchers (SNI) since 2013 and serves as a consultant for Recicladora Limon de Monclova, applying his expertise in metallurgy. He has published 18 research papers in JCR and Scopus journals and holds two patents related to metal extraction and industrial waste recycling. His work extends to mentoring graduate students and contributing to the scientific community through editorial roles and thesis evaluations. With a strong commitment to sustainable practices and technological innovation, Dr. Zamarripa’s research significantly impacts both academic and industrial fields. His dedication to advancing materials science and his continuous contributions to industrial innovation make him a distinguished candidate for the Best Scholar Award in Research.


Professional Profile



Education


Dr. Gregorio Gonzalez Zamarripa holds a PhD in Materials Science from Saltillo Institute of Technology, which he earned in 2011. His doctoral research focused on hydrometallurgical processes for the recovery of precious metals, earning him the Best Doctoral Thesis Award from the General Direction in Higher Technological Education (DGEST), Mexico. In addition to his PhD, he pursued advanced graduate coursework in Metallic Materials and Materials Science Engineering at Instituto Tecnológico Superior de Monclova (ITSM) between 2018 and 2024. Dr. Zamarripa’s academic journey is marked by a deep focus on applied material sciences, with expertise in developing sustainable methods for metal extraction and wastewater treatment. His educational background combines both theoretical knowledge and practical applications, bridging the gap between scientific research and industrial needs. Over his career, he has expanded his knowledge in areas such as pyrolysis, nanocomposites, and metallurgical waste recycling, reflecting his continuous pursuit of scientific excellence and technological innovation. His education forms the foundation for his multidisciplinary research and his significant contributions to the fields of materials engineering and environmental sustainability.


Professional Experience


Dr. Gregorio Gonzalez Zamarripa currently serves as an Associate Professor at Tecnológico Nacional de México, Instituto Tecnológico Superior de Monclova, where he has been contributing since 2011. His professional journey encompasses 46 years of experience in basic sciences and engineering, with a specific focus on materials recovery from industrial by-products. As a researcher in hydrometallurgy, he leads projects on metal extraction, waste management, and the development of nanomaterials. Beyond academia, he actively collaborates with Recicladora Limon de Monclova as a consultant, offering expertise in metallurgical processes and waste valorization. Dr. Zamarripa also mentors graduate students in mechanical engineering and renewable energy, contributing to the development of the next generation of researchers. His editorial roles include serving as a JCR reviewer for the Hydrometallurgy journal and acting as a CONACYT evaluator. He also participates as an external thesis reviewer for doctoral candidates at Saltillo Institute of Technology. His combined academic and industrial experiences position him as a leading expert in the fields of metal recovery, sustainable technology, and advanced materials science, making him a valuable asset to both the scientific community and industrial partners.


Research Interests


Dr. Gregorio Gonzalez Zamarripa’s research interests center on hydrometallurgy, wastewater treatment, and advanced material recovery. His work emphasizes developing sustainable techniques for metal extraction from industrial residues, particularly focusing on gold, silver, and other precious metals. He is also interested in pyrolysis, exploring innovative methods to convert plastic waste into hydrocarbons, addressing both environmental and industrial challenges. Another key area of interest is the development of graphene-based nanocomposites for antibacterial applications, which has potential implications for healthcare and environmental safety. His recent projects include the removal of heavy metals from wastewater and the creation of magnetic precursor powders from strontium-contaminated water. Dr. Zamarripa is also engaged in waste valorization, focusing on transforming industrial by-products into valuable materials. His multidisciplinary research reflects a commitment to technological innovation, sustainability, and practical solutions to industrial challenges. Through ongoing collaborations with academic and industrial partners, he continues to explore new frontiers in materials science, with a focus on delivering real-world applications that bridge scientific research and industrial implementation.


Research Skills


Dr. Gregorio Gonzalez Zamarripa possesses a diverse set of research skills across multiple domains in materials science and environmental engineering. He is highly proficient in hydrometallurgical processes, including the extraction and recovery of precious metals such as gold and silver from industrial waste. His expertise extends to pyrolysis techniques, where he has developed processes to convert plastic waste into hydrocarbons for energy recovery. Additionally, Dr. Zamarripa is skilled in the synthesis of nanomaterials, including graphene-based nanocomposites, for antibacterial and industrial applications. He has hands-on experience in wastewater treatment, specializing in the removal of heavy metals and contaminants from industrial effluents. His technical capabilities also include patent development, with two patents related to metal recovery and industrial waste recycling. As a research mentor, he guides graduate students in advanced materials characterization, analytical techniques, and industrial process optimization. His comprehensive research skills, combined with industry-focused applications, make him a versatile researcher who addresses critical challenges in sustainable technology and environmental innovation.


Awards and Honors


Dr. Gregorio Gonzalez Zamarripa’s distinguished career has been recognized through numerous awards and honors. In 2011, he received the Best Doctoral Thesis Award from General Direction in Higher Technological Education (DGEST), Mexico, for his groundbreaking research in hydrometallurgy. Since 2013, he has been a member of the National System of Researchers (SNI), acknowledging his sustained contributions to scientific research in materials science. His work has also earned him two patents, including a process for strontium removal and an intensive melting furnace for recovering metals from slags, underscoring his innovative approach to industrial challenges. Dr. Zamarripa has further distinguished himself as a CONACYT evaluator and external thesis reviewer at Saltillo Institute of Technology, reflecting his academic leadership and expertise. His 18 publications in JCR and Scopus journals highlight his research excellence and global impact. These accolades reflect his commitment to advancing materials science, sustainable solutions, and technological innovation on both national and international levels.


Conclusion


Dr. Gregorio Gonzalez Zamarripa is an exceptional candidate for the Best Scholar Award in Research, demonstrating outstanding expertise in materials science, hydrometallurgy, and waste recovery. With 46 years of academic and professional experience, 18 publications, and two patents, he has made significant contributions to both scientific knowledge and industrial practice. His work addresses real-world challenges, such as metal recovery, waste valorization, and sustainable processes, making a lasting impact in both academia and industry. His dedication to mentorship, collaboration, and technological innovation makes him an ideal candidate for this prestigious recognition.


Publications Top Notes


    

  1. Title: “Recovery of fine particles of activated carbon with gold by the electrocoagulation process using a Taguchi experimental design”
    2. 



    

  • Authors: Rodrigo Martínez-Peñuñuri, José R. Parga-Torres, Jesús L. Valenzuela-García, Alejandro M. García-Alegría, Gregorio González-Zamarripa
    • 

  • Year: 2023
    •