Zhengwei You | Materials Science | Outstanding Scientist Award

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Prof. Dr. Zhengwei You | Materials Science | Outstanding Scientist Award

Chair of the Department of Composite Materials from Donghua University, China

Professor Dr. Zhengwei You is a leading figure in polymer and biomaterials research, currently serving as Chair of the Department of Composite Materials and Full Professor at Donghua University. With a robust academic and industry background, he has contributed significantly to advanced fiber materials, polyurethane elastomers, 3D printing, biomedicine, and flexible electronics. His research outputs include 96 peer-reviewed publications, over 60 patents, and two book chapters, with numerous papers in high-impact journals such as Nature Medicine, Nature Communications, and Advanced Materials. He has delivered over 50 keynote and invited lectures worldwide and serves on multiple editorial boards and professional committees in materials science, biomaterials, and engineering. His work is frequently highlighted by the National Natural Science Foundation of China and national media. With an H-index of 45 and over 7,600 Google Scholar citations, Prof. You is recognized as an influential researcher whose contributions bridge academia and industrial innovation. His leadership extends beyond research, including roles as chairman, vice-chair, and standing committee member across several scientific and academic societies. Prof. You’s multifaceted expertise, combined with his leadership in research management, places him at the forefront of materials science research in China and internationally.

Professional Profile

Education

Prof. Zhengwei You completed his Bachelor of Science degree in Applied Chemistry at Shanghai Jiao Tong University (1996–2000), where he gained strong foundational knowledge in chemical sciences. He went on to pursue his Ph.D. in Organic Chemistry at the prestigious Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, from 2002 to 2007. This doctoral training provided him with in-depth expertise in advanced organic synthesis, molecular design, and material characterization, establishing the technical basis for his later breakthroughs in polymer materials and biomaterials. His solid academic preparation in China’s top-ranked institutions positioned him well to integrate chemistry with materials science, allowing him to make key contributions to the fields of advanced fiber materials, elastomers, and biomedical engineering. This rigorous education also fostered his ability to lead interdisciplinary research and collaborate across chemistry, materials, and bioengineering domains, both in academia and industry.

Professional Experience

Prof. Zhengwei You has built a distinguished professional career spanning academia, research, and industry. He is currently Chair of the Department of Composite Materials at Donghua University (since 2016) and Full Professor at the State Key Laboratory of Advanced Fiber Materials (since 2013). His international experience includes roles as Visiting Research Assistant Professor (2011–2012) and Postdoctoral Associate (2009–2011) at the McGowan Institute of Regenerative Medicine, University of Pittsburgh, and as a Postdoctoral Associate (2007–2008) at Georgia Institute of Technology and Emory University. Notably, he also worked as an Innovation Manager for Bayer MaterialScience (2012–2013), giving him a strong bridge between academic research and industrial application. Earlier in his career, he served on the faculty at Shanghai Jiao Tong University (2000–2002). Beyond his institutional roles, Prof. You has held leadership positions in numerous professional societies, serving on editorial boards and technical committees and actively contributing to research governance, ethics, and scientific development in materials and biomaterials fields.

Research Interests

Prof. Zhengwei You’s research interests span polymers, biomaterials, polyurethane, and elastomers, with applications in 3D printing, biomedicine, and flexible electronics. He is particularly focused on designing advanced materials that exhibit superior mechanical strength, self-healing properties, dynamic crosslinking, and biocompatibility. His work integrates fundamental polymer science with cutting-edge technologies such as additive manufacturing and biofabrication to create next-generation medical devices, tissue scaffolds, and wearable electronics. Prof. You’s research also addresses the synthesis and characterization of smart materials that can respond to external stimuli and deliver tailored functionalities. He combines organic chemistry, materials science, and bioengineering principles to drive innovations at the interface of healthcare and technology. His interdisciplinary approach has led to breakthroughs in areas such as mechanoactive mineralization scaffolds for bone regeneration, dynamic polyurethanes for medical applications, and novel fiber materials for flexible electronics, all of which are highly relevant for advancing both clinical practice and industrial applications.

Research Skills

Prof. Zhengwei You possesses advanced research skills in polymer synthesis, organic chemistry, materials characterization, and biomaterials engineering. He is highly proficient in designing and fabricating novel elastomeric and polyurethane materials with dynamic crosslinking and self-healing properties. His expertise includes mechanical testing, thermal analysis, rheological assessment, and microstructural characterization using advanced techniques such as SEM, TEM, AFM, and spectroscopy. Prof. You has deep experience in 3D printing technologies, including biofabrication of scaffolds for tissue engineering, and the development of flexible and wearable electronic devices. Additionally, his research management skills encompass leading large interdisciplinary teams, securing research funding, filing patents, and publishing in top-tier scientific journals. His ability to translate fundamental research into practical applications demonstrates his strength in bridging laboratory discoveries with real-world solutions. With over 50 invited presentations, editorial board memberships, and active participation in international collaborations, Prof. You is not only technically skilled but also an influential research leader.

Awards and Honors

Prof. Zhengwei You has received widespread recognition for his contributions to materials science and biomaterials research. His research has been frequently highlighted by major funding agencies such as the National Natural Science Foundation of China and national media, including China Science Daily and the China Blue Book of New Material Technology Development. He has secured more than 60 patents and published over 90 peer-reviewed papers in highly ranked journals, with numerous articles appearing in Nature Medicine, Advanced Materials, and Angewandte Chemie. His leadership roles across multiple scientific societies reflect his outstanding reputation in the field, including serving as chairman, vice chairman, and standing committee member in prominent national and international organizations. Additionally, Prof. You’s editorial appointments, such as on the boards of Bioactive Materials, Advanced Fiber Materials, and Chinese Journal of Polymer Science, underline his scientific excellence. His invited keynote and plenary lectures at international conferences further showcase the high esteem in which his peers hold his research achievements.

Conclusion

In conclusion, Prof. Zhengwei You stands out as an exceptional candidate for the Best Researcher Award due to his sustained, high-impact contributions to polymer science, biomaterials, and advanced fiber materials. His innovative research in polyurethane, elastomers, and biofabrication has resulted in numerous patents, top-tier publications, and real-world applications in healthcare and flexible electronics. Beyond his research output, Prof. You has demonstrated exemplary leadership by guiding interdisciplinary research teams, serving on influential editorial boards, and playing key roles in professional organizations. While his research portfolio is already robust, potential areas for future growth include expanding international collaborations and further enhancing translational impact to bring laboratory discoveries into widespread clinical or industrial use. Overall, Prof. You’s combination of scientific innovation, leadership, and broad recognition makes him a highly deserving recipient of this award, reflecting both his individual excellence and his ongoing contributions to advancing materials science on a global scale.

Publications Top Notes

  1. Title: Multiple dynamic bonds enable high mechanical strength and efficient room-temperature self-healable polyurethane for triboelectric nanogenerators
    Authors: Zhang, Wenwen; Xuan, Huixia; Xu, Xiaofei; Guan, Qingbao; You, Zhengwei
    Journal: Science China Chemistry
    Year: 2025

  2. Title: Dynamic cross-linked topological network reconciles the longstanding contradictory properties of polymers
    Authors: Wu, Zekai; Chu, Chengzhen; Jin, Yuhui; Zhang, Wenwen; You, Zhengwei
    Journal: Science Advances
    Year: 2025

  3. Title: One-step fabrication of ultrathin porous Janus membrane within seconds for waterproof and breathable electronic skin
    Authors: Ni, Yufeng; Li, Bing; Chu, Chengzhen; Chen, Shuo; You, Zhengwei
    Journal: Science Bulletin
    Year: 2025
    Citations: 2

  4. Title: Mitochondria-inspired general strategy simultaneously enhances contradictory properties of commercial polymers
    Authors: Wang, Yuepeng; Yang, Lei; Qian, Bo; Jia, Yujie; You, Zhengwei
    Journal: Materials Today
    Year: 2025

  5. Title: Low-Cost Intrinsic Flame-Retardant Bio-Based High Performance Polyurethane and its Application in Triboelectric Nanogenerators
    Authors: Zhang, Xiaoyu; Yan, Xixian; Zeng, Fanglei; Guan, Qingbao; You, Zhengwei
    Journal: Advanced Science
    Year: 2025

  6. Title: Sequence-controlled dynamic covalent units enable decoupling of mechanical and self-healing performance of polymers
    Authors: Zhang, Luzhi; Huang, Hongfei; Sun, Lijie; Tan, Hui; You, Zhengwei
    Journal: Science China Chemistry
    Year: 2025

  7. Title: Readily recyclable, degradable, stretchable, highly conductive, anti-freezing and anti-drying glycerohydrogel for triboelectric nanogenerator
    Authors: Jiang, Sihan; Wang, Yang; Tian, Meiqin; Sun, Wei; You, Zhengwei
    Journal: Chemical Engineering Journal
    Year: 2025
    Citations: 1

  8. Title: Construction of room-temperature self-healing polyurethane-based phase change composites for thermal control and energy supply
    Authors: Ouyang, Yuling; Xu, Xiaofei; Li, Yingqian; Guan, Qingbao; You, Zhengwei
    Journal: Science China Chemistry
    Year: 2025

  9. Title: Magnetically Guided Mechanoactive Mineralization Scaffolds for Enhanced Bone Regeneration
    Authors: Guo, Xuran; Tao, Zaijin; Dai, Zhenzhen; You, Zhengwei; Jiang, Jia
    Journal: Advanced Functional Materials
    Year: 2025

  10. Title: Multilevel neurium-mimetic individualized graft via additive manufacturing for efficient tissue repair
    Authors: Kong, Lingchi; Gao, Xin; Yao, Xiangyun; Qian, Yun; Fan, Cunyi
    Journal: Nature Communications
    Year: 2024
    Citations: 5

Hadi Hijazi | Materials Science | Best Researcher Award

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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

  • 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

  • Publication Date: October 30, 2024

 

Zhiyong Dai | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Zhiyong Dai | Materials Science | Best Researcher Award

Associate Professor from Bohai Shipbuilding Vocational College, China

Zhiyong Dai is currently serving as an Associate Professor at Bohai Shipbuilding Vocational College, where he has made significant contributions in the field of materials science and engineering, particularly in welding and high-temperature resistant alloys. With a solid academic background culminating in a Doctorate in Materials Processing Engineering from Shenyang University of Technology (2024), he has combined theoretical knowledge with practical teaching and research experience. Over his academic and professional journey, Dr. Dai has been dedicated to both educational excellence and scientific inquiry. His teaching spans core courses in metallurgy, welding technology, and material properties. His research has produced impactful findings on the mechanical behavior and strengthening mechanisms of Inconel 625 and other advanced nickel-based alloys under extreme conditions. He has published in several high-impact journals, including Materials Science and Engineering A and Journal of Materials Research and Technology. His commitment to academic mentorship is evident from his active involvement in curriculum development and participation in student innovation projects. With a combination of applied industrial focus and strong academic contributions, Dr. Dai stands out as a valuable candidate for recognition such as the Best Researcher Award.

Professional Profile

Education

Zhiyong Dai has built a comprehensive and specialized educational foundation in the field of materials science and engineering. He began his academic journey at Liaoning Petrochemical University, where he earned his Bachelor’s degree in Metallurgical Engineering in 2011. He continued at the same institution to pursue a Master’s degree in Materials Science, which he completed in 2014. His growing interest in the advanced mechanical and physical properties of materials led him to enroll in a Ph.D. program in Materials Processing Engineering at Shenyang University of Technology, where he completed his doctorate in 2024. His doctoral research focused on the hot deformation behavior, strengthening mechanisms, and creep deformation of nickel-based alloys—particularly Inconel 625—under high-temperature conditions. This advanced academic training has equipped him with a deep understanding of metallurgical principles, material failure analysis, and solidification theory. The progression from undergraduate to doctoral studies shows a clear and consistent focus on developing both the theoretical and applied aspects of materials engineering, particularly in welding and high-temperature applications. Throughout his educational journey, Dr. Dai has also completed various professional development programs in higher education and has earned a certification as a university-level teacher from the Liaoning Provincial Department of Education.

Professional Experience

Dr. Zhiyong Dai has accumulated nearly a decade of teaching and research experience at Bohai Shipbuilding Vocational College, where he began his academic career in January 2015. He currently holds the position of Associate Professor and has taught a wide range of subjects, including Principles of Metal Melting, Welding Methods and Technology, and Ship Materials and Welding Processes. His pedagogical work has focused on integrating theoretical knowledge with practical application, providing students with essential industry-oriented skills. Beyond classroom instruction, he has played a pivotal role in guiding students through national and regional academic competitions, often earning accolades for both students and himself as a supervising instructor. His professional growth is marked by steady career progression, moving from Assistant Lecturer in 2015 to Lecturer in 2017, and being promoted to Associate Professor in 2024. Additionally, Dr. Dai has actively participated in academic research and curriculum development, contributing to several internal institutional projects focused on vocational training, modern apprenticeship models, and school-enterprise collaboration. This professional trajectory reflects a dedication to both teaching excellence and applied research, reinforcing his impact on vocational education and positioning him as a candidate deserving of national academic recognition.

Research Interests

Zhiyong Dai’s research interests lie at the intersection of materials science, welding engineering, and high-temperature alloy performance. He is particularly focused on the development and performance evaluation of nickel-based and nitrogen-containing alloys under extreme thermal and mechanical conditions. His recent studies have explored the creep deformation behavior, intermediate temperature brittleness, and tensile properties of Inconel 625 deposited metal and similar advanced materials. His work contributes valuable insights into the mechanisms that govern strength and failure in high-performance alloys used in aerospace, marine, and energy industries. Additionally, Dr. Dai is interested in improving welding materials and processes, especially those involving flux-cored wires and laser positioning devices. He also engages in educational research related to vocational training models and the development of innovation-driven talent in technical institutions. His combined focus on fundamental material behavior and applied welding techniques bridges the gap between theoretical research and industrial application. With a commitment to both scientific advancement and vocational education, his research is aligned with national priorities for high-end manufacturing and skilled labor development, further substantiating his suitability for prestigious research awards.

Research Skills

Dr. Zhiyong Dai possesses a diverse set of research skills that enable him to conduct comprehensive investigations into material behavior and welding technologies. He is adept in high-temperature mechanical testing, microstructural characterization, and metallurgical analysis, including creep testing and tensile strength evaluation of nickel-based alloys. His research utilizes both traditional metallographic methods and advanced analytical techniques to study deformation mechanisms, phase transformation, and grain structure evolution under various processing conditions. He also has practical experience in welding simulation, laser alignment tools, and arc welding systems, contributing to the development of innovative welding materials and methodologies. In addition to his laboratory skills, Dr. Dai is proficient in academic writing and technical reporting, with several Q1 and Q2 journal publications to his credit. He has also led or participated in funded research projects focused on modern apprenticeship systems and industry-academia collaboration. His ability to integrate experimental research with educational innovation showcases his multidisciplinary skill set. Furthermore, he is competent in the use of English for academic purposes, and has passed CET-4, demonstrating his capability to engage in international research communication.

Awards and Honors

Dr. Zhiyong Dai has received multiple recognitions throughout his professional career for both academic and instructional excellence. His awards span individual achievements, team leadership in competitions, and excellence in innovation. Notable honors include a First Prize in the Huludao City Natural Science Academic Achievement Awards in 2017, and a Third Prize for Technical Innovation in Laser Positioning Device Development in 2023. As a mentor, he earned the Instructor Award at the National Nonferrous Metal Vocational College Skills Competition (Aluminum Welding, 2017) and has guided students to success in events such as the “Challenge Cup” Liaoning Province Undergraduate Academic Science and Technology Competition. Additionally, he has received awards for educational guidance and technical paper writing, including third-place honors in faculty skills and student mental health initiatives. His consistent recognition over the years underscores his impact as an educator and researcher. His patent contributions on novel welding alloys and preparation methods also demonstrate his commitment to technological advancement. These achievements reflect his ability to balance academic rigor with applied technical expertise, making him a distinguished candidate for the Best Researcher Award.

Conclusion

In conclusion, Dr. Zhiyong Dai exemplifies the qualities of an outstanding researcher and educator in the field of materials science and engineering. His academic journey reflects a steady progression through increasingly specialized fields, culminating in high-impact research on high-temperature alloy performance and innovative welding technologies. With a strong portfolio of journal publications, patents, and successful research projects, he has demonstrated both depth and breadth in his scholarly contributions. Moreover, his extensive teaching experience and active involvement in student mentorship and academic competitions highlight his dedication to educational excellence. Dr. Dai’s work bridges the critical gap between theoretical material behavior and real-world industrial applications, aligning well with national goals for technological advancement and skilled workforce development. His recognition at local and national levels further attests to his professional competence and academic influence. Considering his contributions to scientific research, education, and innovation, Dr. Dai stands out as a compelling nominee for the Best Researcher Award. He has not only advanced the frontiers of his field but has also inspired the next generation of technical experts, making him a worthy recipient of this honor.

Publication Top Notes

  1. Study on creep properties and deformation mechanisms of novel nickel-based deposited metal
    Authors: Zhiyong Dai, Rongchun Wan, Yunhai Su, Yingdi Wang
    Journal: Advanced Engineering Materials
    Date: 2025-04-22
    DOI: 10.1002/adem.202500182
    Type: Journal Article

  2. Study on the tensile properties and deformation mechanism of high-temperature resistant nitrogen-containing nickel-based welding material deposited metal
    Authors: Zhiyong Dai, Yunhai Su, Yingdi Wang, Taisen Yang, Xuewei Liang
    Journal: Materials Science and Engineering: A
    Date: 2024-06
    DOI: 10.1016/j.msea.2024.146671
    Type: Journal Article

  3. Study of corrosion behavior of Inconel 625 cladding metal in KCl–MgCl₂ molten salt under isothermal and thermal cycling conditions
    Authors: Taisen Yang, Guiqing Zhang, Zhiyong Dai, Xuewei Liang, Yingdi Wang, Yunhai Su
    Journal: Journal of Materials Science
    Date: 2023-08
    DOI: 10.1007/s10853-023-08823-7
    Type: Journal Article

 

Kun Lan | Materials Science | Best Researcher Award

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Prof. Kun Lan | Materials Science | Best Researcher Award

Professor From Inner Mongolia University, China

Dr. Kun Lan is currently a Principal Investigator at the College of Energy Materials and Chemistry, Inner Mongolia University. With a research focus on crystalline mesoporous materials, Dr. Lan has contributed significantly to the field of materials chemistry, authoring over 70 peer-reviewed publications in top-tier journals such as Nature Chemistry, JACS, and Advanced Materials. His academic journey spans esteemed institutions including Lanzhou University, Fudan University, and the University of California, Riverside. His interdisciplinary work bridges chemistry, nanotechnology, and renewable energy applications. As head of the K Lab, he leads a team developing novel mesostructures with relevance to sustainable technologies and energy storage. Dr. Lan has earned multiple national and institutional recognitions for his research excellence, including the National Natural Science Foundation of China grants and the BTR New-Energy Scientific Contest Award. He is also an active member of the scientific community, serving on editorial boards and peer-review panels for international journals. Known for his strong mentorship, innovative approaches to porous material synthesis, and his deep engagement in academic collaboration, Dr. Lan is committed to advancing the frontiers of energy material science through both fundamental discoveries and practical innovations.

Professional Profile

Education

Dr. Kun Lan’s academic path began at Lanzhou University, where he earned his Bachelor of Science in Chemistry in 2013. During his undergraduate years, he developed a foundational understanding of chemical synthesis and material characterization, which sparked his lasting interest in functional materials. Motivated by his growing curiosity, Dr. Lan pursued his Ph.D. in Chemistry at Fudan University under the mentorship of Prof. Dongyuan Zhao, a globally recognized authority in mesoporous materials. He earned his doctorate in 2020, producing a highly cited body of work focused on the design and synthesis of crystalline mesostructures. His Ph.D. research addressed challenges in structural precision and functional integration in porous materials, contributing significantly to the understanding of mesophase control. In 2018–2019, he was a visiting doctoral student at the University of California, Riverside, where he expanded his research scope through international collaboration and exposure to cutting-edge laboratory techniques. These formative academic experiences equipped Dr. Lan with a robust scientific foundation and a global perspective, both of which continue to inform his research direction. His education has been instrumental in developing the skills and mindset necessary for tackling pressing challenges in materials chemistry and renewable technologies.

Professional Experience

Dr. Kun Lan’s professional journey is marked by a steady progression through prestigious academic and research institutions. From 2018 to 2019, he undertook a visiting research appointment at the University of California, Riverside, where he enhanced his understanding of nanomaterial assembly and characterization in an international setting. Following the completion of his Ph.D. in 2020, Dr. Lan served as a Postdoctoral Fellow at Fudan University, where he worked closely with Prof. Dongyuan Zhao. During this time, he deepened his expertise in the controlled synthesis of mesoporous materials and published extensively in high-impact journals. In June 2022, Dr. Lan joined the College of Energy Materials and Chemistry at Inner Mongolia University as a Principal Investigator, where he established the K Lab. As a PI, he leads interdisciplinary research focused on mesostructure design for energy-related applications. He mentors graduate and undergraduate students, secures competitive research funding, and actively contributes to the academic community through collaborations, peer reviews, and conference presentations. His leadership has propelled K Lab into a dynamic research environment known for innovation and academic rigor. Dr. Lan’s career reflects a dedication to scientific excellence, international collaboration, and the development of next-generation researchers in energy materials science.

Research Interests

Dr. Kun Lan’s research lies at the intersection of materials chemistry and sustainable technology, with a focus on the precision synthesis of crystalline mesoporous materials. He is particularly interested in controlling the atomic and mesostructural architecture of porous systems to enhance their performance in catalysis, energy storage, and separation technologies. His work explores the fundamental principles of assembly chemistry, aiming to understand and manipulate the self-organization of building blocks into ordered frameworks. A key objective of his research is to design novel mesostructures with high surface area, tunable porosity, and tailored functionality for renewable technology applications. These include advanced batteries, supercapacitors, and carbon capture materials. Dr. Lan is also committed to developing scalable synthetic routes that bridge the gap between laboratory innovation and industrial relevance. His interdisciplinary approach integrates concepts from solid-state chemistry, colloidal science, and nanotechnology, and often involves collaboration across chemistry, physics, and engineering domains. By addressing critical energy and environmental challenges through materials design, Dr. Lan’s research contributes to the development of sustainable technologies and green manufacturing processes. His work continues to push the boundaries of what is possible in the rational design of hierarchical and hybrid porous materials.

Research Skills

Dr. Kun Lan possesses a comprehensive skill set that spans advanced synthesis, structural characterization, and application testing of functional materials. He is an expert in templating strategies for constructing crystalline mesoporous materials, with extensive experience in sol–gel chemistry, surfactant-assisted assembly, and confined space synthesis. His lab proficiency includes a wide range of material characterization techniques, such as small-angle X-ray scattering (SAXS), high-resolution transmission electron microscopy (HRTEM), N₂ adsorption-desorption isotherms, and solid-state NMR, enabling him to thoroughly investigate structural and textural properties. Dr. Lan is adept at using advanced software tools for 3D structural modeling and diffraction analysis, as well as programming for data processing. He also has hands-on experience in electrochemical testing for batteries and supercapacitors, including cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), and galvanostatic charge-discharge (GCD) measurements. In addition, Dr. Lan is skilled in project management, grant writing, and academic publishing, with over 70 peer-reviewed articles. He regularly collaborates with national and international research teams, and actively mentors graduate students, contributing to capacity building in materials research. His broad technical and leadership capabilities support the successful execution of interdisciplinary projects targeting energy, environmental, and catalytic applications.

Awards and Honors

Dr. Kun Lan has received numerous awards in recognition of his academic excellence and contributions to materials chemistry. His accolades began with the prestigious CSC State Scholarship Fund and the Tongji-Clearon Outstanding Academician Award in 2018. In 2019, he was honored with the Baosteel Excellent Student Award, followed by the title of Outstanding Graduate of Fudan University in 2020. His postdoctoral research earned him further distinction, including the 3rd Fudan Postdoctoral Venture Competition Award and the 1st BTR New-Energy Scientific Contest Award in 2021. In the same year, he won the Nano Research Oral Prize at the 21st Chinese Zeolite Conference and was recognized with the Excellent Doctoral Thesis Award by Fudan University in 2023. Dr. Lan has secured competitive funding from national and provincial bodies, such as the Fudan Super Postdoctoral Program, the 67th China Postdoctoral Science Foundation, and the National Natural Science Foundation of China (NSFC). He is also supported by regional talent programs including the “Junma” Program and the Grassland Talent Program. His leadership potential has been further recognized through appointments to editorial boards and invitations to review for top-tier journals like Angewandte Chemie, Advanced Materials, and Nature Protocols.

Conclusion

Dr. Kun Lan stands at the forefront of research in mesoporous materials and their applications in renewable energy technologies. With a robust academic background, diverse international experience, and a consistent record of impactful publications, he has established himself as a dynamic and influential scientist. Through the K Lab at Inner Mongolia University, Dr. Lan continues to pursue groundbreaking work in materials chemistry, fostering innovation and collaboration across disciplines. His efforts in mentorship and scientific outreach have inspired a new generation of researchers. The breadth of his research—from fundamental studies in self-assembly to practical solutions for energy storage—demonstrates his commitment to addressing global challenges through chemistry. His extensive publication record, awards, and ongoing participation in national research programs reflect a strong and growing impact in the field. As an educator, collaborator, and innovator, Dr. Kun Lan embodies the qualities of a future scientific leader in sustainable materials research. His continued work promises to deliver valuable insights and technologies that will shape the future of energy and materials science.

Publications Top Notes

  1. Metal-based mesoporous frameworks as high-performance platforms in energy storage and conversion
    Authors: Rongyao Li, Xu Wen, Yuqi Zhao, Sicheng Fan, Qiulong Wei, Kun Lan
    Year: 2025

  2. DFT-Guided Design of Dual Dopants in Anatase TiO2 for Boosted Sodium Storage
    Authors: Shuang Li, Xu Wen, Xin Miao, Rongyao Li, Wendi Wang, Xiaoyu Li, Ziyang Guo, Dongyuan Zhao, Kun Lan
    Year: 2024

  3. Conversion of Z-Scheme to type-II in dual-defective V2O5/C3N4 heterostructure for durable hydrogen evolution
    Authors: Jingyu Zhang, Jialong Li, Jinwei He, Yalin He, Zelin Wang, Shuang Li, Zhanli Chai, Kun Lan
    Year: 2024

  4. Lanthanum-Integrated Porous Adsorbent for Effective Phosphorus Removal
    Authors: Yalin He, Xingyue Qi, Jialong Li, Wendi Wang, Jingyu Zhang, Lanhao Yang, Mei Xue, Kun Lan
    Year: 2024

  5. Ordered Mesoporous Crystalline Frameworks Toward Promising Energy Applications
    Authors: Jialong Li, Rongyao Li, Wendi Wang, Kun Lan, Dongyuan Zhao
    Year: 2024

  6. Intrinsic Surface-Redox Sodium-Ion Storage Mechanism of Anatase Titanium Oxide toward High-Rate Capability
    Authors: Kun Lan (and team, unspecified here)
    Year: 2023

  7. Nanodroplet Remodeling Strategy for Synthesis of Hierarchical Multi-chambered Mesoporous Silica Nanoparticles
    Authors: Kun Lan (and team, unspecified here)
    Year: 2023

  8. Construction of Type-II Heterojunctions in Crystalline Carbon Nitride for Efficient Photocatalytic H2 Evolution
    Authors: Jingyu Zhang, Zhongliang Li, Jialong Li, Yalin He, Haojie Tong, Shuang Li, Zhanli Chai, Kun Lan
    Year: 2023

  9. Stepwise Monomicelle Assembly for Highly Ordered Mesoporous TiO2 Membranes with Precisely Tailored Mesophase and Porosity
    Authors: Kun Lan, Lu Liu, Jiayu Yu, Yuzhu Ma, Jun-Ye Zhang, Zirui Lv, Sixing Yin, Qiulong Wei, Dongyuan Zhao
    Year: 2023

  10. Constructing Unique Mesoporous Carbon Superstructures via Monomicelle Interface Confined Assembly
    Authors: Kun Lan
    Year: 2022

  11. Synthesis of Ni/NiO@MoO3-x Composite Nanoarrays for High Current Density Hydrogen Evolution Reaction
    Authors: Kun Lan
    Year: 2022

  12. Versatile Synthesis of Mesoporous Crystalline TiO2 Materials by Monomicelle Assembly
    Authors: Kun Lan
    Year: 2022

  13. Modular super-assembly of hierarchical superstructures from monomicelle building blocks
    Authors: Kun Lan
    Year: 2022

  14. Functional Ordered Mesoporous Materials: Present and Future
    Authors: Kun Lan
    Year: 2022

  15. Precisely Designed Mesoscopic Titania for High-Volumetric-Density Pseudocapacitance
    Authors: Kun Lan
    Year: 2021

  16. Streamlined Mesoporous Silica Nanoparticles with Tunable Curvature from Interfacial Dynamic-Migration Strategy for Nanomotors
    Authors: Kun Lan
    Year: 2021

  17. General Synthesis of Ultrafine Monodispersed Hybrid Nanoparticles from Highly Stable Monomicelles
    Authors: Kun Lan
    Year: 2021

  18. Precisely Controlled Vertical Alignment in Mesostructured Carbon Thin Films for Efficient Electrochemical Sensing
    Authors: Kun Lan
    Year: 2021

  19. Surface-Confined Winding Assembly of Mesoporous Nanorods
    Authors: Kun Lan
    Year: 2020

  20. Interfacial Assembly Directed Unique Mesoporous Architectures: From Symmetric to Asymmetric
    Authors: Kun Lan
    Year: 2020

  21. Stable Ti3+ Defects in Oriented Mesoporous Titania Frameworks for Efficient Photocatalysis
    Authors: Kun Lan, Ruicong Wang, Qiulong Wei, Yanxiang Wang, Anh Hong, Pingyun Feng, Dongyuan Zhao
    Year: 2020

  22. Branched Mesoporous TiO2 Mesocrystals by Epitaxial Assembly of Micelles for Photocatalysis
    Authors: Kun Lan
    Year: 2020

  23. Synthesis of uniform ordered mesoporous TiO2 microspheres with controllable phase junctions for efficient solar water splitting
    Authors: Kun Lan
    Year: 2019

  24. Defect-engineering of mesoporous TiO2 microspheres with phase junctions for efficient visible-light driven fuel production
    Authors: Kun Lan
    Year: 2019

  25. Janus Mesoporous Sensor Devices for Simultaneous Multivariable Gases Detection
    Authors: Kun Lan
    Yar: 2019

  26. Two-Dimensional Mesoporous Heterostructure Delivering Superior Pseudocapacitive Sodium Storage via Bottom-Up Monomicelle Assembly
    Authors: Kun Lan
    Year: 2019

  27. Confined Interfacial Monomicelle Assembly for Precisely Controlled Coating of Single-Layered Titania Mesopores
    Authors: Kun Lan
    Year: 2019

  28. Confinement synthesis of hierarchical ordered macro-/mesoporous TiO2 nanostructures with high crystallization for photodegradation
    Authors: Kun Lan
    Year: 2019

  29. Fully printable hole-conductor-free mesoscopic perovskite solar cells based on mesoporous anatase single crystals
    Authors: Kun Lan
    Year: 2018

  30. Mesoporous TiO2 Microspheres with Precisely Controlled Crystallites and Architectures
    Authors: Kun Lan
    Year: 2018

  31. Mesoporous TiO2 /TiC@C Composite Membranes with Stable TiO2-C Interface for Robust Lithium Storage
    Authors: Kun Lan
    Year: 2018

  32. Uniform Ordered Two-Dimensional Mesoporous TiO2 Nanosheets from Hydrothermal-Induced Solvent-Confined Monomicelle Assembly
    Authors: Kun Lan, Yao Liu, Wei Zhang, Yong Liu, Ahmed Elzatahry, Ruicong Wang, Yongyao Xia, Dhaifallah Al-Dhayan, Nanfeng Zheng, Dongyuan Zhao
    Year: 2018

  33. Constructing Three-Dimensional Mesoporous Bouquet-Posy-like TiO2 Superstructures with Radially Oriented Mesochannels and Single-Crystal Walls
    Authors: Yong Liu, Kun Lan, Shushuang Li, Yongmei Liu, Biao Kong, Geng Wang, Pengfei Zhang, Ruicong Wang, Haili He, Yun Ling, et al.
    Year: 2016

  34. Template synthesis of metal tungsten nanowire bundles with high field electron emission performance
    Authors: Yong Liu, Kun Lan, Mahir H. Es-Saheb, Ahmed A. Elzatahry, Dongyuan Zhao
    Year: 2016

  35. Surfactant-templating strategy for ultrathin mesoporous TiO2 coating on flexible graphitized carbon supports for high-performance lithium-ion battery
    Authors: Kun Lan
    Year: 2016

  36. Ordered Macro/Mesoporous TiO2 Hollow Microspheres with Highly Crystalline Thin Shells for High-Efficiency Photoconversion
    Authors: Yong Liu, Kun Lan, Abdulaziz A. Bagabas, Pengfei Zhang, Wenjun Gao, Jingxiu Wang, Zhenkun Sun, Jianwei Fan, Ahmed A. Elzatahry, Dongyuan Zhao
    Year: 2015

  37. Mesoporous TiO2 Mesocrystals: Remarkable Defects-Induced Crystallite-Interface Reactivity and Their in Situ Conversion to Single Crystals
    Authors: Yong Liu, Yongfeng Luo, Ahmed A. Elzatahry, Wei Luo, Renchao Che, Jianwei Fan, Kun Lan, Abdullah M. Al-Enizi, Zhenkun Sun, Bin Li, et al.
    Year: 2015

Tan Wang | Materials Science | Best Researcher Award

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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

Jian-gang Guo | Materials Science | Best Researcher Award

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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
    • Year: 2025

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

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

  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. 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. 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. 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. 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. Superconductivity in Pressurized Trilayer La₄Ni₃O₁₀−δ Single Crystals

    • Authors: Zhu Yinghao, Peng Di, Zhang Enkang, Guo Jianggang, Zhao Jun
    • Year: 2024
    • Citations: 41

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

  • Authors: Wang Guobin, Sheng Da, Yang Yunfan, Guo Jianggang, Chen Xiaolong
  • Year: 2024
  • Citations: 10

Gregorio Gonzalez | Materials Science | Best Researcher Award

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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”
  • Authors: Rodrigo Martínez-Peñuñuri, José R. Parga-Torres, Jesús L. Valenzuela-García, Alejandro M. García-Alegría, Gregorio González-Zamarripa
  • Year: 2023

 

XIYA YANG | Materials Science | Women Researcher Award

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Prof. XIYA YANG | Materials Science | Women Researcher Award

Associate Professor at Jinan University, China

Dr. Xiya Yang is an Associate Professor at the Institute of New Energy Technology, College of Physics & Optoelectronic Engineering, Jinan University. With a solid academic foundation and over a decade of experience in cutting-edge research, she has made significant strides in energy harvesting and self-powered sensing systems. Her work focuses on integrating triboelectric, photovoltaic, and other hybrid effects to address critical challenges in sustainable energy and Internet of Things (IoT) technologies. Dr. Yang has been recognized with numerous prestigious awards and has a robust publication record in high-impact journals, reflecting her dedication and innovation. She is also a passionate educator, mentoring students to achieve excellence in research and competitions. Dr. Yang is committed to advancing interdisciplinary research, fostering innovation, and contributing to the global energy sustainability agenda.

Professional Profile

Education

Dr. Xiya Yang holds a Ph.D. in Materials Science and Engineering from the City University of Hong Kong, which she completed in 2017. Prior to that, she earned a Master’s degree with Distinction in Energy and Environmental Engineering from the same institution in 2013. Her undergraduate studies were completed at Shandong University of Science and Technology, where she graduated as an Outstanding Graduate in Automation Engineering in 2012. This rigorous academic background has provided her with a strong foundation in energy systems and advanced materials, setting the stage for her impactful research career.

Professional Experience

Dr. Yang currently serves as an Associate Professor at the College of Physics & Optoelectronic Engineering, Jinan University, a role she has held since January 2024. Prior to this, she was an Associate Professor at the College of Information Science and Technology at the same university from 2018 to 2023. She also completed a postdoctoral fellowship at the School of Energy and Environment, City University of Hong Kong, from 2017 to 2018. Her professional experience spans teaching, research, and mentoring, with a focus on sustainable energy technologies and innovation. Dr. Yang’s contributions to the academic and research community have been instrumental in advancing knowledge in her field.

Research Interests

Dr. Yang’s research interests lie at the intersection of energy sustainability and advanced materials. Her primary focus is on self-powered micro/nano electromechanical systems and hybrid energy harvesting technologies. She explores innovative solutions to harness solar, wave, wind, rain, and human kinetic energy for self-powered sensing systems. Additionally, she delves into the coupling effects of piezoelectric, triboelectric, electromagnetic, and photovoltaic mechanisms to optimize energy efficiency. Dr. Yang is also interested in passive and active power management designs, contributing to the development of next-generation IoT systems. Her interdisciplinary approach aims to address global challenges in energy sustainability and smart sensing.

Research Skills

Dr. Yang possesses a diverse skill set in experimental design, advanced materials characterization, and energy systems integration. She is proficient in developing hybrid nanogenerators and triboelectric sensors, emphasizing coupling effects for enhanced energy efficiency. Her expertise includes designing and fabricating self-powered sensing systems, as well as optimizing power management strategies. Dr. Yang has extensive experience in project management, having served as the principal investigator for multiple national and provincial research grants. Her ability to mentor students and lead interdisciplinary teams further highlights her capabilities in both research and education.

Awards and Honors

Dr. Yang’s contributions to research and education have been recognized with numerous awards. She received the 2022 Guangdong Natural Science Award (Second Prize) and was named a Jinan Outstanding Young Scholar in 2021. Other accolades include the Jinan University “Major Achievement Contribution Award” (2019-2020) and the Young Talents distinction in 2018. She has also earned recognition for her teaching excellence, including the Third Prize in Jinan University’s New Teachers Teaching Competition. Her achievements reflect her dedication to advancing both academic excellence and impactful research.

Conclusion

Dr. Xiya Yang’s impressive academic background, extensive professional experience, and groundbreaking research contributions make her a distinguished candidate for the Best Researcher Award. Her work in hybrid energy harvesting and self-powered sensing systems addresses critical global challenges, demonstrating both innovation and impact. Through her dedication to mentorship and interdisciplinary collaboration, she has fostered the next generation of researchers and advanced knowledge in sustainable energy technologies. Dr. Yang’s achievements and ongoing contributions position her as a leading figure in her field, deserving of this prestigious recognition.

Publication Top Notes

  1. Machine learning-assisted wearable triboelectric-electromagnetic sensor for monitoring human motion feature
    Authors: Zhao, L., Jia, S., Fang, C., Hu, Y., Yang, X.
    Year: 2025
  2. Columnar Macrocyclic Molecule Tailored Grain Cage to Stabilize Inorganic Perovskite Solar Cells with Suppressed Halide Segregation
    Authors: Liu, N., Duan, J., Li, H., Yang, X., Tang, Q.
    Year: 2024
    Citations: 2
  3. A Compact-Sized Fully Self-Powered Wireless Flowmeter Based on Triboelectric Discharge
    Authors: Wan, D., Xia, X., Wang, H., Yang, X., Zi, Y.
    Year: 2024
    Citations: 2
  4. Suppressing charge recombination by synergistic effect of ferromagnetic dual-tribolayer for high output triboelectric nanogenerator
    Authors: Liu, L., Li, J., Tian, Z., Yang, X., Ou-Yang, W.
    Year: 2024
    Citations: 7
  5. Conductive dual-network hydrogel-based multifunctional triboelectric nanogenerator for temperature and pressure distribution sensing
    Authors: Zhao, L., Fang, C., Qin, B., Yang, X., Poechmueller, P.
    Year: 2024
    Citations: 6
  6. Biomimetic bimodal haptic perception using triboelectric effect
    Authors: He, S., Dai, J., Wan, D., Xia, X., Zi, Y.
    Year: 2024
    Citations: 12
  7. Reinforced SnO2 tensile-strength and “buffer-spring” interfaces for efficient inorganic perovskite solar cells
    Authors: Zhao, Y., Gao, L., Wang, Q., Duan, J., Tang, Q.
    Year: 2024
    Citations: 8
  8. Triboelectric gait sensing analysis system for self-powered IoT-based human motion monitoring
    Authors: Zhao, L., Guo, X., Pan, Y., Poechmueller, P., Yang, X.
    Year: 2024
    Citations: 17
  9. Electrostatic-driven self-assembled chitin nanocrystals (ChNCs)/MXene films for triboelectric nanogenerator
    Authors: He, Y., Zhao, L., Guo, X., Luo, B., Liu, M.
    Year: 2024
    Citations: 6
  10. CsPbBr3 nanocrystals as electron and ion “Reservoirs” to induce energy transfer and grain reconstruction for efficient carbon-based inorganic perovskite solar cells
    Authors: Duan, J., Zhang, C., Liu, Y., Yang, X., Tang, Q.
    Year: 2024
    Citations: 4

 

 

 

 

 

Alexander Ikeuba | Materials Science | Best Researcher Award

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Dr. Alexander Ikeuba | Materials Science | Best Researcher Award

Researcher at West Virginia University, United States

Dr. Alexander Immaanyikwa Ikeuba is an esteemed scholar and professional whose career is marked by academic excellence and impactful contributions to his field. Renowned for his multidisciplinary expertise, Dr. Ikeuba has published extensively in various reputable journals, establishing himself as a thought leader in his domain. His commitment to advancing knowledge and fostering innovation underscores his reputation as a scholar of global repute. Beyond academia, Dr. Ikeuba is celebrated for his dedication to mentoring emerging talents and his ability to bridge the gap between theoretical research and practical applications. His professional ethos reflects a deep commitment to fostering progress and creating value through research, teaching, and collaboration.

Professional Profile

Education

Dr. Alexander Ikeuba’s academic journey is a testament to his relentless pursuit of excellence. He earned his undergraduate degree from [Institution Name] with a specialization in [Subject/Field], distinguishing himself as a top-performing student. He later pursued advanced degrees, including a master’s and a doctorate from [Institution Name(s)], where his research focused on [Research Area]. His academic milestones are complemented by various certifications and specialized training programs that have further solidified his expertise. Through rigorous education, Dr. Ikeuba cultivated a strong foundation that has enabled him to make significant contributions to his chosen field.

Professional Experience

Dr. Ikeuba’s professional career spans over [Number] years, during which he has held prominent roles in academia, research institutions, and industry. As a professor at [Institution Name], he has taught numerous courses, inspiring students and fostering intellectual growth. In addition, his roles as a consultant and collaborator with leading organizations have allowed him to apply his knowledge to solve real-world challenges. His extensive portfolio includes leadership positions, project management roles, and active participation in interdisciplinary research teams. This wealth of experience has positioned him as a versatile and dynamic professional with a global impact.

Research Interest

Dr. Ikeuba’s research interests lie at the intersection of [Field 1] and [Field 2], focusing on addressing contemporary challenges through innovative solutions. His areas of focus include [Specific Topics, e.g., sustainable development, advanced materials, artificial intelligence, etc.]. He is particularly passionate about exploring emerging trends and technologies that have the potential to transform industries and improve societal well-being. By bridging theoretical frameworks with practical applications, his research aims to create sustainable solutions that address critical global issues.

Research Skills

Dr. Ikeuba possesses a robust set of research skills that underpin his scholarly work. These include proficiency in advanced statistical analysis, qualitative and quantitative methodologies, and the use of cutting-edge software and tools. His expertise in [Specific Tools or Techniques, e.g., machine learning algorithms, laboratory procedures, etc.] has been instrumental in achieving groundbreaking results. Furthermore, his ability to collaborate across disciplines and his strong analytical mindset enable him to tackle complex problems effectively. His research acumen is complemented by exceptional writing and presentation skills, which ensure his findings are effectively disseminated to both academic and non-academic audiences.

Awards and Honors

Over the course of his illustrious career, Dr. Ikeuba has been the recipient of numerous awards and honors. These include [Specific Award Titles, e.g., “Best Researcher Award,” “Excellence in Teaching Award”], which reflect his outstanding contributions to academia and society. His achievements have been recognized at both national and international levels, further solidifying his status as a leading figure in his field. In addition, his membership in prestigious organizations and societies, such as [Specific Societies], is a testament to his commitment to advancing knowledge and fostering innovation.

Conclusion

Dr. Alexander Immaanyikwa Ikeuba is a distinguished academic, researcher, and professional whose contributions continue to make a lasting impact. His dedication to excellence in education, research, and professional practice underscores his role as a transformative leader in his field. Through his innovative work, mentorship, and collaboration, he has not only advanced the boundaries of knowledge but also inspired others to pursue excellence. As he continues to push the frontiers of his discipline, Dr. Ikeuba remains a beacon of inspiration for scholars and professionals worldwide.

Publication Top Notes

    • Journal: Journal of the Electrochemical Society
    • Year: 2018
    • Citations: 67
  • Alkaloid and non-alkaloid ethanolic extracts from seeds of Garcinia kola as green corrosion inhibitors of mild steel in H2SO4 solution
    • Authors: AI Ikeuba, PC Okafor, UJ Ekpe, EE Ebenso
    • Journal: International Journal of Electrochemical Science
    • Year: 2013
    • Citations: 63
  • Understanding the galvanic corrosion of the Q-phase/Al couple using SVET and SIET
    • Authors: AI Ikeuba, B Zhang, J Wang, EH Han, W Ke
    • Journal: Journal of Materials Science & Technology
    • Year: 2019
    • Citations: 52
  • Electrochemical, TOF-SIMS and XPS studies on the corrosion behavior of Q-phase in NaCl solutions as a function of pH
    • Authors: AI Ikeuba, B Zhang, J Wang, EH Han, W Ke
    • Journal: Applied Surface Science
    • Year: 2019
    • Citations: 42
  • Understanding the electrochemical behavior of bulk-synthesized MgZn2 intermetallic compound in aqueous NaCl solutions as a function of pH
    • Authors: AI Ikeuba, F Kou, H Duan, B Zhang, J Wang, EH Han, W Ke
    • Journal: Journal of Solid State Electrochemistry
    • Year: 2019
    • Citations: 42
  • Comparative study of the inhibition effects of alkaloid and non-alkaloid fractions of the ethanolic extracts of Costus afer stem on the corrosion of mild steel in 5 M …
    • Authors: IE Uwah, AI Ikeuba, BU Ugi, VM Udowo
    • Journal: Global Journal of Pure and Applied Sciences
    • Year: 2013
    • Citations: 39
  • Experimental and theoretical evaluation of aspirin as a green corrosion inhibitor for mild steel in acidic medium
    • Authors: AI Ikeuba, OB John, VM Bassey, H Louis, AU Agobi, JE Ntibi, FC Asogwa
    • Journal: Results in Chemistry
    • Year: 2022
    • Citations: 38

 

Hua-Yong Liao | Materials Science | Best Researcher Award

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Dr. Hua-Yong Liao | Materials Science | Best Researcher Award

Teacher at Changzhou University, China

Dr. Hua-yong Liao, a distinguished scholar in materials science and polymer rheology, serves as a faculty member at Changzhou University, China. With over 15 years of experience in academia and research, he has made significant contributions to understanding polymer processing and rheology. He has published extensively in high-impact journals, with research spanning topics such as dynamic rheological behavior of polymer blends and advanced composite materials. Dr. Liao has also secured over 40 patents, showcasing his innovative approach to experimental methodologies. His expertise includes the design and application of advanced rheometric instruments, which bridge the gap between academic research and industrial applications. Additionally, his international experience at the National University of Singapore reflects his global recognition and collaborative endeavors.

Professional Profile

Education

Dr. Hua-yong Liao earned his Ph.D. in Mechanical Engineering from Zhejiang University, China, in 2007, specializing in polymer rheology under the mentorship of Professor Yu-Run Fan. He completed his Master’s degree in Mechanical Engineering at Beijing University of Chemical Engineering in 2003, following his Bachelor of Engineering in the same field from Zhengzhou University in 1999. His academic training provided a strong foundation in polymer science, preparing him for groundbreaking research in materials engineering.

Professional Experience

Since 2007, Dr. Liao has been a dedicated faculty member at Changzhou University, focusing on materials science and engineering. His work involves teaching, mentoring students, and conducting innovative research in polymer rheology and processing. In 2013-2014, he was a research fellow at the National University of Singapore, where he worked with renowned expert Nhan Phan-Thien. Prior to his academic career, Dr. Liao gained industrial experience as a technician at Wuhan Aerospace Corrugated Pipe Company from 1999 to 2000. This diverse background has equipped him with both academic insights and practical skills for advancing polymer science.

Research Interests

Dr. Liao’s research interests lie at the intersection of polymer processing and rheology. He specializes in exploring the dynamic rheological behavior of polymer blends, such as low-density polyethylene and polypropylene composites. His work also investigates compatibilization techniques for advanced polymer composites and foaming abilities of modified polyethylene terephthalate. With a focus on bridging theoretical and experimental approaches, his research aims to optimize polymer performance for industrial applications, making significant contributions to materials science and engineering.

Research Skills

Dr. Liao possesses advanced expertise in using rotational and capillary rheometers to study the flow and deformation of polymer melts. He is skilled in designing innovative rheometric instruments, as evidenced by his patented bidirectional extrusion capillary rheometers. His proficiency extends to experimental polymer processing techniques, data analysis, and mathematical modeling of polymer behavior. Additionally, he has strong skills in academic writing, securing intellectual property, and developing methodologies that integrate experimental and industrial requirements.

Awards and Honors

Dr. Liao has been recognized for his groundbreaking contributions to polymer science through numerous accolades. He holds over 40 patents, including innovations in rheometric equipment that have advanced the study of polymer rheology. His publications in esteemed journals highlight his prominence in the field, earning him respect as a leading researcher. Furthermore, his international fellowship at the National University of Singapore underscores his global recognition and commitment to collaborative research in materials science.

Conclusion

Hua-yong Liao is a strong candidate for the Best Researcher Award due to his extensive work in polymer rheology, notable patent portfolio, and commitment to advancing materials science. While his technical expertise and contributions are exceptional, enhancing his research impact through collaborations, leadership in large projects, and broader engagement with the scientific community would further solidify his position as a leading researcher.

Publication Top Notes

  • Rheological investigation on polyethylene terephthalate (PET) filled with hollow glass beads
    • Authors: Liao, H.-Y., Chen, H.-L., Tao, G.-L., Liu, C.-L.
    • Year: 2024
  • Investigation on Foaming Ability of Modified Polyethylene Terephthalate (PET) Composites Prepared Using Compression Molding
    • Authors: Liao, H.-Y., Gao, J., Tao, G.-L., Liu, C.-L.
    • Year: 2024
  • Rheology of a polypropylene/low-density polyethylene blending melt: Fitting dynamic rheological data by Palierne model and Lee and Park model
    • Authors: Liao, H.-Y., Liao, R.-R., Li, S.-Q., Liu, C.-L., Tao, G.-L.
    • Year: 2022
    • Citations: 2
  • A polypropylene/high-density polyethylene blend compatibilized with an ethylene-propylene-diene monomer block copolymer: Fitting dynamic rheological data by emulsion models with a physical scheme
    • Authors: Liao, H.-Y., Tao, G.-L., Liu, C.-L., Gong, F.-H.
    • Year: 2016
    • Citations: 7
  • Dynamic rheological behavior of reactively compatibilized polypropylene/polyamide 6 blending melts
    • Authors: Liao, H.-Y., Zheng, L.-Y., Hu, Y.-B., Tao, G.-L., Liu, C.-L.
    • Year: 2015
    • Citations: 9
  • Dynamic rheological behavior of two LDPE/HDPE binary blending melts
    • Authors: Liao, H.-Y., Qi, L.-Y., Tao, G.-L., Liu, C.-L.
    • Year: 2015
    • Citations: 4
  • Rheological behavior of a LDPE/PS/SBS blending melt
    • Authors: Liao, H.-Y., Lu, H.-B.
    • Year: 2014
    • Citations: 3
  • Dynamic rheological behavior of PP/HDPE/EPDM ternary blends
    • Authors: Liao, H., Shi, X., Tao, G.
    • Year: 2014
  • Impact strength and melt flow rate of high-density polyethylene melts
    • Authors: Liao, H., Tao, G.
    • Year: 2013
    • Citations: 4
  • Mould foaming of HDPE/LDPE blends
    • Authors: Liao, H., Tao, G.
    • Year: 2013
    • Citations: 2