Sandra Cunha Gonçalves | Materials Science and Engineering | Women Researcher Award

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Prof. Dr. Sandra Cunha Gonçalves | Materials Science and Engineering | Women Researcher Award

Research Teacher | Federal Institute of Bahia | Brazil

Prof. Dr. Sandra Cunha Gonçalves has developed a solid academic and scientific career in Civil Engineering, Sustainability, and Environmental Studies, focusing on innovative solutions for the reuse of waste materials in the construction industry. Her research emphasizes solid waste management and the development of eco-friendly materials that incorporate vegetal fibers, modified starch, recycled gypsum, and other industrial by-products to minimize environmental impacts and promote sustainable practices in social housing. Gonçalves has contributed to advancing sustainable construction technologies through the creation of composites and biocomposites with improved physical and mechanical properties, offering alternatives to conventional materials with high energy consumption. Her ongoing projects explore life cycle analysis of materials, the use of green coconut fibers, and polymeric emulsions in gypsum matrices, generating significant results for structural efficiency and environmental performance. Her scientific output includes publications in national and international journals, book chapters, and conference presentations on sustainability, bioconstruction, and waste management. In addition to her research, she promotes extension activities that integrate social technology, environmental education, and vernacular architecture, strengthening the connection between science, culture, and community. At the Federal Institute of Bahia, Gonçalves leads research groups focused on material innovation and environmental education, mentoring new researchers committed to socio-environmental responsibility and construction efficiency. Her professional journey is distinguished by a strong dedication to sustainability, the integration of applied science with technical education, and the continuous pursuit of viable solutions that balance technical performance with the preservation of natural resources.

Profile: ORCID
Featured Publications
Gonçalves, S. C., da Silva Junior, M. F., Souza, M. T., de Amorim Júnior, N. S., & Ribeiro, D. V. (2025). Physicomechanical properties of recycled gypsum composites with polyvinyl acetate emulsion and treated short green coconut fibers. Buildings.

Junsong Yang – Materials Science and Engineering – Best Researcher Award

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Junsong Yang - Materials Science and Engineering - Best Researcher Award

Professor | Bengbu Medical University | China

Junsong Yang, affiliated with Bengbu Medical University in China, has established a solid research footprint with contributions that span advanced materials, nanotechnology, and photocatalysis. The profile records 22 publications that collectively garnered 66 citations, reflecting recognition from the scientific community and an h-index of 5, demonstrating both productivity and impact. The works highlight innovative approaches in material design, such as the preparation of Ti₃C₂/SA-TCPP composites through π–π interactions, which significantly improved hydrogen peroxide production and enabled efficient photocatalytic self-Fenton degradation of pollutants like 2,4-dichlorophenol, underscoring the environmental relevance of this research. Another notable study developed ratiometric FRET-encoded Zr-MOF@Au-FAM/TAMRA nanoassemblies integrated with tetrahedral framework nucleic acid-functionalized magnetic beads and DNA walkers, advancing ultrasensitive detection methods for antibiotics such as enrofloxacin and ciprofloxacin, indicating a strong interdisciplinary connection between chemistry, biotechnology, and environmental safety. The author’s research trajectory shows a consistent focus on combining functional nanomaterials with catalytic and sensing applications, addressing both energy conversion and pollution remediation challenges. Co-authorship with 55 collaborators reveals an extensive professional network, enhancing the interdisciplinary scope of the research. The publication record in high-impact journals, including Separation and Purification Technology and Chemical Engineering Journal, illustrates the quality and relevance of contributions in both applied and fundamental science. The consistent engagement with pressing global issues such as environmental pollution, sustainable chemical processes, and biomedical detection technologies positions the work as impactful and forward-looking. While awarded grants are not listed, the productivity and growing citation base suggest increasing recognition and potential for future funded projects. The scholarly activities demonstrate a balance between methodological innovation and practical application, making Junsong Yang’s contributions valuable for advancing modern chemical engineering and materials science, with clear implications for environmental sustainability, energy solutions, and public health monitoring.

Profile: Scopus 
Featured Publications:

Preparation of Ti3C2/SA-TCPP via π–π interaction for the enhanced production of H2O2 and the highly efficient photocatalytic-self-Fenton degradation of 2,4-dichlorophenol. (2025). Separation and Purification Technology.

Ratiometric FRET encoding Zr-MOF@Au-FAM/TAMRA nano assemblies based on tetrahedral framework nucleic acid-functionalized magnetic beads and DNA walker for ultrasensitive quantifying enrofloxacin and ciprofloxacin. (2025). Chemical Engineering Journal.

Yaxing Liu – Materials Science and Engineering – Best Researcher Award

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Mr. Yaxing Liu - Materials Science and Engineering - Best Researcher Award

lecturer | Taiyuan University of Technology | China

Mr. Yaxing Liu has established strong expertise in the field of mechanical design and theory with a research focus on advanced rolling technology, material forming processes, and fatigue analysis of high-performance steels. His work investigates the mechanisms of strip edge defects, deformation behaviors in composite rolling, and fatigue performance under varying stress conditions, providing valuable insights for enhancing the precision, durability, and efficiency of manufacturing systems. He has contributed to the development of innovative control strategies for trimming processes and created accurate modeling approaches for predicting warping and deformation during steel and aluminum thin strip composite rolling. His research integrates both theoretical modeling and experimental validation to solve complex industrial challenges, ensuring significant improvements in quality control and defect prevention in metal forming industries. In addition to scholarly publications in high-impact journals, Liu’s contributions include patents addressing roll convexity adjustment mechanisms and compensation methods for roll diameter defects in rolling mills, showcasing his ability to translate fundamental research into practical engineering solutions. His continuous engagement in material behavior analysis under stress, defect mitigation techniques, and optimization of manufacturing processes reflects a clear trajectory toward advancing modern mechanical design and metallurgical engineering. With active collaboration across disciplines and consistent innovation in mechanical system optimization, his research strengthens both academic knowledge and industrial application. Yaxing Liu’s work demonstrates a balance of theoretical insight, experimental application, and practical implementation, marking him as a valuable contributor to the development of advanced rolling and forming technologies with wide relevance to the steel and aluminum industries. 155 Citations by 139 documents, 57 Documents, 7 h-index View.

Profile: Scopus
Featured Publications:

  1. Effect of multi‒directional forging on the evolution of intermetallic precipitates and mechanical properties in novel light refractory high-entropy alloys. (2025). Intermetallics.

  2. DDFNet: real-time salient object detection with dual-branch decoding fusion for steel plate surface defects. (2025). Journal of Iron and Steel Research International.

  3. Study on influence and mechanism of steel / aluminum composite thin strips preparation process on interfacial bonding strength. (2025). Suxing Gongcheng Xuebao Journal of Plasticity Engineering.

  4. Research on unbonded defect imaging method of corrugated clad plate based on laser ultrasonics. (2025). Measurement Journal of the International Measurement Confederation.

  5. Effect of two-pass rolling of textured roll and polished roll on surface topography and mechanical properties of 316L stainless steel ultra-thin strip. (2025). Journal of Iron and Steel Research International.

Dr. Yuhai Dou – Materials Chemistry – Best Researcher Award

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Dr. Yuhai Dou - Materials Chemistry - Best Researcher Award

University of Shanghai for Science and Technology - China

AUTHOR PROFILR

GOOGLE SCHOLAR

🧬 SUMMARY

Dr. Yuhai Dou is a trailblazing materials scientist specializing in atomically thin nanomaterials for energy conversion and storage. With a Ph.D. from the University of Wollongong and extensive research experience across China and Australia, he has pioneered several high-impact studies in electrocatalysis, water splitting, and rechargeable batteries. Dr. Dou is a Professor at the University of Shanghai for Science and Technology and has served in roles such as ARC DECRA Fellow and Research Fellow at Griffith University. He boasts a publication record of over 90 papers in top-tier journals with an H-index of 45, over 7500 citations, and coverage in leading science media outlets. His innovations have been recognized through multiple awards, fellowships, and funded projects totaling millions in CNY and AUD. He continues to contribute significantly to next-generation energy materials research and global scientific collaboration.

📘 EARLY ACADEMIC PURSUITS

Dr. Yuhai Dou began his academic journey in materials science at Central South University, where he earned both his bachelor's and master's degrees with a focus on powder metallurgy. During his early career, he displayed an aptitude for applied research, developing high-silicon aluminum alloys and oxide dispersion-strengthened steels. His passion for advanced materials led him to pursue doctoral studies at the University of Wollongong under the guidance of esteemed mentors like Prof. Shi Xue Dou and A/Prof. Ziqi Sun. His Ph.D. focused on atomically thin nanomaterials for lithium/sodium-ion batteries and catalytic oxygen evolution reactions. A notable milestone during his doctoral years included a visiting research stint at Beihang University, where he explored superwetting materials for oil spill collection. These formative years equipped Dr. Dou with a solid foundation in nanomaterials, electrochemistry, and sustainable energy technologies, which continue to shape his scientific pursuits today.

🏛️ PROFESSIONAL ENDEAVORS

Dr. Dou's professional journey reflects a dynamic blend of academic excellence and international exposure. He began as an Associate Research Fellow at the University of Wollongong, advancing to Research Fellow and DECRA Fellow at Griffith University, where he explored single-atom catalysts and vacancy engineering. Returning to China, he held professorships at the Shandong Institute of Advanced Technology and currently serves as Professor at the University of Shanghai for Science and Technology. Across these roles, he has led cutting-edge research on atomically thin materials for electrocatalysis and clean energy. Dr. Dou has also been actively involved in mentoring young researchers, chairing academic sessions, and contributing to major international conferences. His strong academic leadership and commitment to translational research have positioned him as a key figure in the global materials science community, driving innovation in sustainable energy technologies.

🔬 CONTRIBUTIONS AND RESEARCH FOCUS

At the core of Dr. Dou’s research is the rational design and manipulation of atomically thin nanomaterials to enhance energy conversion and storage systems. He has made significant breakthroughs in water splitting, H2O2 production, oxygen evolution reaction (OER), and the development of next-generation Li/Na-ion batteries. His research integrates defect engineering, cation-vacancy tuning, and single-atom catalyst design, setting new performance benchmarks in electrocatalysis. Dr. Dou's interdisciplinary approach blends computational modeling and experimental methods, supported by prestigious grants from the ARC and Chinese funding agencies. His highly cited reviews and original articles, including in Chemical Reviews and Nature Communications, have influenced academic and industrial strategies toward green energy. Through collaborations and keynotes, he promotes global dialogue in materials research. His work not only addresses energy sustainability but also contributes to the foundational understanding of two-dimensional material science.

🏆 ACCOLADES AND RECOGNITION

Dr. Dou's outstanding research achievements have earned him numerous national and international honors. He is a recipient of the ARC DECRA award, IAAM Medal Nomination, and the China Top Cited Paper Award. His excellence in innovation was recognized with the Military Medal by the Shanghai Government and the “5150” Talent Plan of Jinan. Additional accolades include the Distinguished Expert of Jinan, Taishan Scholar title, and several early-career research grants from Griffith University. His academic leadership is reflected in invitations as keynote speaker, session chair, and panelist at global conferences. With awards from prestigious institutions and governments, Dr. Dou has been consistently identified as an emerging leader in energy materials research. These recognitions underscore his ability to bridge academic inquiry with real-world applications, affirming his role as a global influencer in sustainable energy solutions.

🌍 IMPACT AND INFLUENCE

Dr. Yuhai Dou's influence extends beyond publications and patents—his work impacts global energy policy and industrial innovation. His studies on efficient water-splitting catalysts and next-generation batteries offer promising solutions to energy challenges. Several of his papers are highly cited, appearing in journals with impact factors exceeding 70, and are frequently spotlighted by science media worldwide. He has played a significant role in guiding early-career scientists through mentorship and collaboration. His participation in international consortia, such as ARC Discovery and Vehicle Auto CRC, reflects his strategic integration of academic insight into industry-relevant projects. Dr. Dou’s research has shaped contemporary understanding of low-dimensional materials and continues to inform best practices in nanomaterials engineering for energy applications. As a thought leader, his global reach and interdisciplinary approach advance the transition toward a more sustainable and energy-efficient future.

🚀 LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Dou is poised to expand the boundaries of nanomaterials science through high-risk, high-reward research. With over 26 million CNY in research grants under his leadership, he plans to deepen exploration into defect-modulated 2D materials and scalable electrocatalysts for hydrogen generation. His vision includes fostering cross-disciplinary research that merges artificial intelligence, advanced spectroscopy, and materials informatics. As a mentor and collaborator, he aims to build a global network for innovation in energy storage technologies. His ongoing contributions will likely redefine efficiency standards in catalysis and battery technologies. Dr. Dou’s long-term impact lies in his ability to inspire scientific curiosity, train future leaders, and engineer practical solutions for global sustainability. His legacy is one of scientific rigor, visionary leadership, and unwavering commitment to advancing clean energy science for societal good.

PUBLICATION

Title: Generalized self-assembly of scalable two-dimensional transition metal oxide nanosheets
Authors: Z. Sun, T. Liao, Y. Dou, S.M. Hwang, M.S. Park, L. Jiang, J.H. Kim, S.X. Dou
Journal: Nature Communications, 5 (1), 3813 (2014)

Title: Coexisting single‐atomic Fe and Ni sites on hierarchically ordered porous carbon as a highly efficient ORR electrocatalyst
Authors: Z. Zhu, H. Yin, Y. Wang, C.H. Chuang, L. Xing, M. Dong, Y.R. Lu, ...
Journal: Advanced Materials, 32 (42), 2004670 (2020)

Title: Recent progress in graphite intercalation compounds for rechargeable metal (Li, Na, K, Al)‐ion batteries
Authors: J. Xu, Y. Dou, Z. Wei, J. Ma, Y. Deng, Y. Li, H. Liu, S. Dou
Journal: Advanced Science, 4 (10), 1700146 (2017)

Title: 2D Frameworks of C2N and C3N as New Anode Materials for Lithium‐Ion Batteries
Authors: J. Xu, J. Mahmood, Y. Dou, S. Dou, F. Li, L. Dai, J.B. Baek
Journal: Advanced Materials, 29 (34), 1702007 (2017)

Title: Atomic Layer‐by‐Layer Co₃O₄/Graphene Composite for High Performance Lithium‐Ion Batteries
Authors: Y. Dou, J. Xu, B. Ruan, Q. Liu, Y. Pan, Z. Sun, S.X. Dou
Journal: Advanced Energy Materials, 6 (8), 1501835 (2016)

Title: A yolk–shell structured silicon anode with superior conductivity and high tap density for full lithium‐ion batteries
Authors: L. Zhang, C. Wang, Y. Dou, N. Cheng, D. Cui, Y. Du, P. Liu, M. Al‐Mamun, ...
Journal: Angewandte Chemie International Edition, 58 (26), 8824–8828 (2019)

Wioletta Raczkiewicz – Materials Science and Engineering – Best Researcher Award

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Wioletta Raczkiewicz - Materials Science and Engineering - Best Researcher Award

Kielce University of Technology - Poland

AUTHOR PROFILE

SCOPUS
GOOGLE SCHOLAR
ORCID

SUMMARY

Wioletta Raczkiewicz is a civil engineering expert with extensive academic and professional engagement in concrete structures, building renovation, and historic building conservation. With nearly three decades of involvement in technical education and structural research, the profile is marked by progressive academic roles at Kielce University of Technology. Key contributions include the development of stochastic models for fiber-reinforced concrete and ongoing dedication to educational and architectural engineering excellence. Current responsibilities as Associate Professor include teaching, mentoring, and research leadership in advanced concrete technologies and structural diagnostics.

EDUCATION

Earned a Master of Engineering in Civil Engineering in 1994 from Kielce University of Technology, with a specialization in Building Renovations and Historic Conservation. The thesis focused on adaptive reconstruction of Villa Zielona into a guesthouse. In 2008, completed a Doctor of Technical Sciences degree in Civil Engineering, specializing in Concrete Structures. The doctoral dissertation investigated stochastic parameter distributions in fiber-reinforced concrete under variable loading, reflecting a high level of analytical and modeling capability within modern structural engineering contexts.

PROFESSIONAL EXPERIENCE

Began professional career in 1995 at the Research Institute of Roads and Bridges in Warsaw, Kielce branch, as a technologist. Continued academic work at Kielce University of Technology from 1997 onward across multiple faculty transformations, evolving from early technical roles to current designation as Associate Professor since December 2023. Over the years, responsibilities have included curriculum development, scientific research, and faculty service. Academic progression reflects long-term contributions in concrete technology, civil infrastructure diagnostics, and the integration of historic and modern construction methods.

RESEARCH INTEREST

Focus areas include fiber-reinforced concrete behavior under variable loads, stochastic modeling in structural engineering, diagnostics of construction materials, and conservation technologies for historical buildings. Interested in the development of innovative rehabilitation solutions and structural assessments through computational and empirical approaches. Emphasizes interdisciplinary integration between modern construction science and architectural heritage preservation. Research aims at improving reliability and sustainability of concrete structures while advancing methodologies in structural health monitoring and damage prediction under real-world operational conditions.

AWARD AND HONOR

Recognized within institutional settings for consistent academic performance and contributions to structural engineering research. While no international honors are explicitly listed, appointment to Associate Professor reflects institutional acknowledgment of scholarly merit and educational impact. Continued involvement in faculty development and mentoring underscores professional credibility and recognition within the academic engineering community. Contributions to doctoral supervision and peer-reviewed scientific work further illustrate recognition and trust in research excellence and educational leadership in civil engineering.

RESEARCH SKILL

Possesses advanced capabilities in stochastic modeling, finite element analysis, material diagnostics, and structural assessment techniques. Proficient in the application of probabilistic methods to evaluate concrete behavior under stress conditions. Skilled in developing interdisciplinary projects involving historic building technologies and sustainable construction practices. Demonstrates technical proficiency in laboratory methods for testing fiber-reinforced composites and interpreting complex data sets for real-world engineering applications. Also experienced in supervising engineering theses and managing collaborative academic research projects with a focus on reliability and material performance.

PUBLICATIONS TOP NOTED

Authored several technical publications in the field of concrete structures and structural modeling. Focus areas in these works include reliability assessment of fiber-reinforced materials and diagnostic techniques in civil engineering structures. Publications contribute to ongoing discourse in probabilistic evaluation of construction materials and are regularly cited within specialized journals of civil engineering and materials science. Key works also address structural behavior under dynamic and cyclic loads, further emphasizing expertise in advanced analysis of concrete and historical restoration frameworks.

Title: Reinforcement corrosion testing in concrete and fiber reinforced concrete specimens exposed to aggressive external factors
Authors: W. Raczkiewicz, M. Bacharz, K. Bacharz, M. Teodorczyk
Journal: Materials

Title: Determination of the linear correlation coefficient between Young’s modulus and the compressive strength in fibre-reinforced concrete based on experimental studies
Authors: A. Czajkowska, W. Raczkiewicz, M. Ingaldi
Journal: Production Engineering Archives

Title: Innovative strengthening of RC columns using a layer of a fibre reinforced concrete
Authors: P. Koteš, M. Vavruš, W. Raczkiewicz
Journal: Acta Polytechnica CTU Proceedings

Title: Temperature impact on the assessment of reinforcement corrosion risk in concrete by galvanostatic pulse method
Authors: W. Raczkiewicz, A. Wojcicki
Journal: Applied Sciences

Title: Use of polypropylene fibres to increase the resistance of reinforcement to chloride corrosion in concretes
Author: W. Raczkiewicz
Journal: Science and Engineering of Composite Materials

CONCLUSION

Wioletta Raczkiewicz exemplifies scholarly excellence in civil engineering, particularly in structural analysis and building conservation. The academic and research trajectory demonstrates a commitment to combining theoretical modeling with practical engineering applications. Contributions to educational development, research innovation, and technical diagnostics reinforce a leadership position within the field. With a stable academic tenure and impactful scientific output, the profile remains a valuable asset to structural engineering advancement, especially in concrete technologies and heritage restoration methodologies.

Linnan Bi – Materials Science and Engineering – Best Researcher Award

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Linnan Bi - Materials Science and Engineering - Best Researcher Award

University of Electronic Science and Technology of China - China

AUTHOR PROFILE

GOOGLE SCHOLER

⚡ RESEARCH THEMES AND SCIENTIFIC

Dr. Linnan Bi’s research themes include solid-state batteries, composite electrode design, high-conductivity solid electrolytes, ionic transport mechanisms, and nanoporous material systems. His mission is to redefine the structural landscape of energy storage materials through nanoscale engineering, aiming to overcome the limitations of traditional liquid-based systems. With a strong foundation in both theoretical and experimental techniques, he continues to investigate the core challenges in battery technology—safety, longevity, and efficiency. Through persistent scientific inquiry and innovation, he contributes to advancing the global pursuit of sustainable and reliable energy solutions.

🎓 EARLY ACADEMIC PURSUITS

Dr. Linnan Bi began his academic journey with a strong foundation in Materials Science and Engineering at the University of Electronic Science and Technology of China (UESTC). His early academic training was distinguished by a focus on nanomaterials, electrochemistry, and energy storage systems. By the time he completed his Ph.D. in 2024, he had already developed a keen interest in the structural modification of carbon-based materials and their application in advanced battery systems. His graduate research emphasized the integration of theoretical design with practical experimentation, particularly in the realm of lithium and sodium ion batteries. This balance between theory and hands-on experimentation enabled him to build a robust understanding of energy conversion and storage, which has defined the trajectory of his postdoctoral pursuits. His academic excellence was reflected in the rapid progression to postdoctoral research within a top-tier national research facility.

🧑‍🏫 PROFESSIONAL ENDEAVORS

Currently a postdoctoral fellow at the University of Electronic Science and Technology of China, Dr. Bi actively engages in innovative materials research with a strong focus on energy applications. His work encompasses both academic and applied projects, including advanced solid-state electrolyte development and the design of nanoporous carbon structures. He is a critical member of several institutional collaborations with leading Chinese and international universities. His professional activities include overseeing experimental designs, mentoring younger researchers, and publishing high-impact articles. With an eye toward practical innovation, Dr. Bi bridges the gap between laboratory research and industrial implementation. His roles are not only limited to scientific development but also extend into intellectual property, evidenced by his numerous patents in the battery technology sector. These initiatives have reinforced his status as a multifaceted scientist contributing to China’s clean energy and advanced materials sectors.

🔬 CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Bi’s research focuses on the structural optimization of solid-state electrolytes, nanoporous carbons, and advanced electrode materials for lithium and sodium ion batteries. His work explores how electrochemical interfaces evolve during charge-discharge cycles and seeks to improve conductivity and structural compatibility in solid-state battery systems. A notable dimension of his research is the development of heterojunction interfaces and reinforcement frameworks to enhance electrochemical performance and durability. His methodical approach combines simulation modeling with rigorous experimentation, allowing for comprehensive material characterization and performance validation. His published research, totaling 22 peer-reviewed articles, includes key findings in halide electrolyte performance, covalent organic frameworks in lithium-sulfur systems, and solid polymer electrolytes. His growing patent portfolio further underscores his inventive contributions to sustainable energy storage technologies.

🏅 ACCOLADES AND RECOGNITION

Dr. Linnan Bi has been recognized for both his academic innovation and impactful publications. He was honored in Wiley China’s “Excellent Author Program” for scientific innovation during April–June 2024, a reflection of his contributions to advancing material science in energy sectors. He also received the 5th Xinwei Academic Paper Award and the Xinwei Popularity Award for his high-quality research outputs. These accolades affirm his scientific standing within the Chinese research community and his growing influence internationally. His citation index currently exceeds 420, reflecting significant engagement and acknowledgment from the global scientific community. His patent filings and peer-reviewed articles reflect a mature body of work that balances fundamental science with technological relevance.

🌍 IMPACT AND INFLUENCE

Dr. Bi’s research holds direct relevance to global efforts toward cleaner energy and efficient power storage. By enhancing solid-state battery technology, his work supports the global transition away from fossil fuels and toward sustainable energy systems. His insights into electrolyte-material compatibility and electrode surface engineering are crucial to the development of next-generation batteries for electric vehicles and grid storage. Furthermore, his collaborative work with institutions like Shaanxi University of Science and Technology and Wenzhou University has allowed for wider dissemination and application of his findings. His technical expertise contributes not only to academic discourse but also to industrial product development, making him a key player in China’s evolving energy landscape.

🔮 LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Bi aims to lead pioneering research in high-energy-density and long-life solid-state batteries. He plans to expand on the mechanistic understanding of electrochemical degradation and develop smart, adaptive electrolytes that can self-heal and maintain ionic conductivity over extended lifecycles. His ambition is to build scalable material systems for commercial energy storage devices while maintaining a commitment to environmentally friendly synthesis processes. He envisions greater integration of AI-based modeling and material informatics into battery research. By nurturing interdisciplinary collaborations, publishing transformative research, and contributing to IP development, Dr. Bi seeks to leave a legacy defined by practical breakthroughs and sustainable innovation in material science.

NOTABLE PUBLICATIONS

Title: CoS₂ embedded graphitic structured N-doped carbon spheres interlinked by rGO as anode materials for high-performance sodium-ion batteries
Authors: X. He, L. Bi, Y. Li, C. Xu, D. Lin
Journal: Electrochimica Acta 332, 135453 (2020)

Title: High energy storage density and discharging efficiency in La³⁺/Nb⁵⁺-co-substituted (Bi₀.₅Na₀.₅)₀.₉₄Ba₀.₀₆TiO₃ ceramics
Authors: Y. Yang, H. Wang, L. Bi, Q. Zheng, G. Fan, W. Jie, D. Lin
Journal: Journal of the European Ceramic Society 39 (10), 3051–3056 (2019)

Title: Enhanced Cycling Stability and Rate Capability in a La-Doped Na₃V₂(PO₄)₃/C Cathode for High-Performance Sodium Ion Batteries
Authors: L. Bi, X. Li, X. Liu, Q. Zheng, D. Lin
Journal: ACS Sustainable Chemistry & Engineering 7 (8), 7693–7699 (2019)

Title: Improving electrochemical performance of Na₃(VPO₄)₂O₂F cathode materials for sodium ion batteries by constructing conductive scaffold
Authors: L. Bi, Z. Miao, X. Li, Z. Song, Q. Zheng, D. Lin
Journal: Electrochimica Acta 337, 135816 (2020)

Title: Insight into accelerating polysulfides redox kinetics by BN@MXene heterostructure for Li–S batteries
Authors: Y. Song, P. Tang, Y. Wang, L. Bi, Q. Liang, Y. Yao, Y. Qiu, L. He, Q. Xie, P. Dong, et al.
Journal: Small 19 (38), 2302386 (2023)

Weiwei Zhang – Materials Science and Engineering – Best Researcher Award

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Weiwei Zhang - Materials Science and Engineering - Best Researcher Award

Heze University - China

AUTHOR PROFILE

SCOPUS

🧪 RESEARCH THEMES

Dr. Weiwei Zhang’s core research themes include nanocomposite flame retardancy, interpenetrating polymer networks, polysilsesquioxane-based reinforcement systems, and smart polymer design. Her mission is to create safer, smarter, and more sustainable materials through the innovative integration of polymer science, thermal chemistry, and structural engineering. With a passion for both scientific discovery and practical application, her work seeks to enhance safety performance across industries while promoting greener chemical practices. Dr. Zhang continues to push the boundaries of material science to meet the challenges of the modern world.

🎓 EARLY ACADEMIC PURSUITS

Dr. Weiwei Zhang’s academic journey began with a strong foundation in chemical engineering at Qingdao University, where she completed both her bachelor’s and master’s degrees. She further advanced her expertise by earning a Ph.D. in Materials Science from the Beijing Institute of Technology. Throughout her studies, she consistently ranked among the top students, earning prestigious honors such as Outstanding Doctoral Graduate and the Outstanding Dissertation Award. Her early research included fundamental studies on polysaccharide fibers and advanced flame-retardant composites, which set the stage for her deeper investigations into functional polymers and nanocomposites. These experiences not only shaped her scientific outlook but also sparked a long-term passion for addressing material challenges in safety and sustainability through innovative research in flame-retardant systems and structural materials.

🧑‍🏫 PROFESSIONAL ENDEAVORS

Since January 2022, Dr. Zhang has served as an Associate Professor at the School of Chemistry and Chemical Engineering, Heze University. Her appointment came through the university’s prestigious “Outstanding Doctoral Talent Introduction Program,” which recognizes exceptional young researchers. In this role, she has been instrumental in fostering advanced research programs while mentoring students in polymer and composite material sciences. She balances teaching with research leadership, having secured internal and provincial grants. Her integration into the university has helped establish a robust research environment in material engineering and nanotechnology. Dr. Zhang has also contributed to cross-disciplinary collaborations within the institution, further advancing the university’s profile in applied materials research and sustainable chemical engineering practices.

🔬 CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Zhang's research is centered on functional polymer materials, high-performance composites, and flame-retardant systems. She has explored advanced synthesis methods for silsesquioxane-based nanomaterials and their applications in vinyl ester and epoxy resin systems. Her work integrates experimental investigations with molecular dynamic simulations to uncover structure-property relationships, particularly focusing on mechanical reinforcement, thermal stability, and fire resistance. Her studies on interpenetrating polymer networks, polyhedral oligomeric silsesquioxanes (POSS), and biodegradable fiber spinning techniques provide practical solutions for industries that require materials with superior flame retardancy and durability. These contributions are particularly relevant in the context of safer construction materials, aerospace composites, and sustainable product design.

🏅 ACCOLADES AND RECOGNITION

Dr. Zhang has been consistently recognized for her scientific excellence. During her Ph.D., she was awarded the Outstanding Doctoral Graduate and received multiple first-class scholarships in acknowledgment of her academic and research performance. Her papers have been published in high-impact journals such as Composites Part A & B, Polymer Degradation and Stability, and Journal of Materials Science. Her publication record showcases her dedication to both scientific rigor and real-world application. In recognition of her growing expertise, she has been granted research funding from the Shandong Provincial Natural Science Foundation, highlighting her emerging leadership in flame-retardant material innovation and her ability to compete at both institutional and provincial levels.

🌍 IMPACT AND INFLUENCE

Through her extensive research on flame-retardant nanocomposites, Dr. Zhang is contributing to safer, more sustainable material technologies. Her work on PMPOSS-modified polymers and POSS-reinforced composites has potential applications in transportation, electronics, and construction sectors that demand high-performance and flame-resistant materials. Her findings on transparency, mechanical integrity, and low-smoke emission properties influence both industrial manufacturing processes and safety standards. She continues to collaborate with leading materials scientists across China, further integrating her research into national material innovation strategies. As a teacher and mentor, she is also shaping future chemists and engineers, extending her influence beyond the lab and into future generations of researchers.

🔮 LEGACY AND FUTURE CONTRIBUTIONS

Dr. Zhang aims to establish herself as a leading voice in flame-retardant and multifunctional material development. Her vision includes the integration of eco-friendly flame retardants, biodegradable polymer systems, and advanced fabrication techniques that reduce carbon footprint. In the future, she intends to pursue further interdisciplinary collaborations—merging polymer chemistry with environmental engineering and nanoscience. By expanding on the mechanisms behind flame suppression and thermal resistance, she hopes to contribute foundational knowledge that can be applied to a broad array of safety-critical industries. Through teaching, publishing, and research leadership, she is building a legacy rooted in material innovation and academic excellence.

NOTABLE PUBLICATIONS

Facile synthesis of polyhedral oligomeric silsesquioxanes with excellent thermosetting, fibrous and crystalline properties

Authors: W. Zhang (Weiwei), Y. Niu (Yukuan), W. Zhang (Wenchao), R. Yang (Rongjie)
Journal: European Polymer Journal, 2024

Analysis on the caged structure of polyhedral oligomeric dodecaphenyl silsesquioxane and its condensation mechanism

Authors: D. Zhang (Donglin), H. Zhou (Hailian), R. Yang (Rongjie), W. Zhang (Weiwei), L. Li (Lamei)
Journal: Journal of Molecular Structure, 2023

Ranjit Bariki – Materials Science and Engineering – Best Researcher Award

Published on by Civil Engineering

Ranjit Bariki - Materials Science and Engineering - Best Researcher Award

UAE University - United Arab Emirates

EARLY ACADEMIC PURSUITS

DR. RANJIT BARIKI began his academic journey with a B.Sc. in Chemistry from Utkal University, followed by an M.Sc. and M.Phil. in Inorganic Chemistry at Sambalpur University. Demonstrating an early inclination toward materials science and catalysis, he pursued and completed his Ph.D. at the National Institute of Technology Rourkela in Material Chemistry, under the supervision of Prof. B.G. Mishra. His doctoral research laid a strong foundation in the synthesis and application of porous hybrid materials for sustainable energy and environmental applications.

PROFESSIONAL ENDEAVORS

Dr. Bariki has held several prestigious roles including Postdoctoral Scientist at the American University of Sharjah and UAE University. He also served as a Senior and Junior Research Fellow in India, working extensively on porous hybrid materials. His academic contributions include teaching undergraduate lab courses and guiding master's theses. He has actively participated in scientific editing roles and contributed to knowledge dissemination through freelance editorial work, combining research with communication.

CONTRIBUTIONS AND RESEARCH FOCUS

His research portfolio is richly diverse and centers on the synthesis of metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and advanced semiconductor materials. Dr. Bariki has explored applications in ammonia production, photocatalytic hydrogen evolution, biomass conversion, CO₂ reduction, and wastewater treatment. His work often emphasizes cost-effective, sustainable methods for energy and environmental remediation, utilizing complex nanostructures and heterojunction systems for enhanced photocatalytic activity.

ACCOLADES AND RECOGNITION

Dr. Bariki’s scholarly excellence is reflected in numerous accolades, including the Prof. Dayanidhi Patnaik Memorial Award by the Odisha Chemical Society, qualification in national competitive exams like CSIR-NET and GATE, and an IMA scholarship for academic merit. With over 1,100 citations, an h-index of 19, and multiple Q1 journal publications, his work has earned global recognition in photocatalysis and energy conversion.

IMPACT AND INFLUENCE

His scientific contributions have significant implications in addressing climate and energy challenges, especially through innovations in ammonia synthesis, green hydrogen production, and pollutant degradation. With multiple publications in high-impact journals such as Applied Catalysis B, Inorganic Chemistry, and Chemical Engineering Journal, Dr. Bariki has established a strong footprint in both academic and industrial research communities across India and the UAE.

LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Bariki envisions pioneering sustainable catalytic technologies that bridge academic innovation with industrial application. He aims to continue expanding his work on renewable energy solutions and photocatalysis, fostering collaborations globally. His legacy is being built upon novel catalyst architectures and a dedication to mentoring future chemists and engineers in clean energy technologies.

PUBLICATION EXCELLENCE

With over 25 high-impact publications, Dr. Bariki has significantly enriched literature on multifunctional photocatalysts and green chemistry. His papers reflect a sophisticated understanding of charge migration mechanisms, material heterojunctions, and environmental decontamination strategies. His authorship often leads key projects, as seen in his corresponding author roles, emphasizing leadership in research dissemination.

NOTABLE PUBLICATION

Title: Facile synthesis and photocatalytic efficacy of UiO-66/CdIn₂S₄ nanocomposites with flowerlike 3D-microspheres towards aqueous phase decontamination of triclosan and H₂ evolution
Authors: R. Bariki, D. Majhi, K. Das, A. Behera, B.G. Mishra
Journal: Applied Catalysis B: Environmental 270, 118882 (2020)

Title: Plasmonic Ag nanoparticle decorated Bi₂O₃/CuBi₂O₄ photocatalyst for expeditious degradation of 17α-ethinylestradiol and Cr (VI) reduction: Insight into electron transfer
Authors: D. Majhi, A.K. Mishra, K. Das, R. Bariki, B.G. Mishra
Journal: Chemical Engineering Journal 413, 127506 (2021)

Title: Facile synthesis and application of CdS/Bi₂₀TiO₃₂/Bi₄Ti₃O₁₂ ternary heterostructure: a synergistic multi-heterojunction photocatalyst for enhanced endosulfan degradation and
Authors: K. Das, R. Bariki, D. Majhi, A. Mishra, K.K. Das, R. Dhiman, B.G. Mishra
Journal: Applied Catalysis B: Environmental 303, 120902 (2022)

Title: A facile reflux method for in situ fabrication of a non-cytotoxic Bi₂S₃/β-Bi₂O₃/ZnIn₂S₄ ternary photocatalyst: A novel dual Z-scheme system with enhanced
Authors: D. Majhi, K. Das, R. Bariki, S. Padhan, A. Mishra, R. Dhiman, P. Dash, et al.
Journal: Journal of Materials Chemistry A 8(41), 21729–21743 (2020)

Title: In-situ synthesis of structurally oriented hierarchical UiO-66 (–NH₂)/CdIn₂S₄/CaIn₂S₄ heterostructure with dual S-scheme engineering for photocatalytic renewable H₂ production
Authors: R. Bariki, S.K. Pradhan, S. Panda, S.K. Nayak, D. Majhi, K. Das, B.G. Mishra
Journal: Separation and Purification Technology 314, 123558 (2023)

Ranjit Bariki – Materials Science and Engineering – Best Researcher Award

Published on by Civil Engineering

Ranjit Bariki - Materials Science and Engineering - Best Researcher Award

United Arab Emirates University - India

🎓 EARLY ACADEMIC PURSUITS

DR. RANJIT BARIKI began his academic journey with a B.Sc. in Chemistry from Utkal University, followed by an M.Sc. and M.Phil. in Inorganic Chemistry at Sambalpur University. Demonstrating an early inclination toward materials science and catalysis, he pursued and completed his Ph.D. at the National Institute of Technology Rourkela in Material Chemistry, under the supervision of Prof. B.G. Mishra. His doctoral research laid a strong foundation in the synthesis and application of porous hybrid materials for sustainable energy and environmental applications.

🏛️ PROFESSIONAL ENDEAVORS

Dr. Bariki has held several prestigious roles including Postdoctoral Scientist at the American University of Sharjah and UAE University. He also served as a Senior and Junior Research Fellow in India, working extensively on porous hybrid materials. His academic contributions include teaching undergraduate lab courses and guiding master's theses. He has actively participated in scientific editing roles and contributed to knowledge dissemination through freelance editorial work, combining research with communication.

🔬 CONTRIBUTIONS AND RESEARCH FOCUS

His research portfolio is richly diverse and centers on the synthesis of metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and advanced semiconductor materials. Dr. Bariki has explored applications in ammonia production, photocatalytic hydrogen evolution, biomass conversion, CO₂ reduction, and wastewater treatment. His work often emphasizes cost-effective, sustainable methods for energy and environmental remediation, utilizing complex nanostructures and heterojunction systems for enhanced photocatalytic activity.

🏅 ACCOLADES AND RECOGNITION

Dr. Bariki’s scholarly excellence is reflected in numerous accolades, including the Prof. Dayanidhi Patnaik Memorial Award by the Odisha Chemical Society, qualification in national competitive exams like CSIR-NET and GATE, and an IMA scholarship for academic merit. With over 1,100 citations, an h-index of 19, and multiple Q1 journal publications, his work has earned global recognition in photocatalysis and energy conversion.

🌍 IMPACT AND INFLUENCE

His scientific contributions have significant implications in addressing climate and energy challenges, especially through innovations in ammonia synthesis, green hydrogen production, and pollutant degradation. With multiple publications in high-impact journals such as Applied Catalysis B, Inorganic Chemistry, and Chemical Engineering Journal, Dr. Bariki has established a strong footprint in both academic and industrial research communities across India and the UAE.

🔗 LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Bariki envisions pioneering sustainable catalytic technologies that bridge academic innovation with industrial application. He aims to continue expanding his work on renewable energy solutions and photocatalysis, fostering collaborations globally. His legacy is being built upon novel catalyst architectures and a dedication to mentoring future chemists and engineers in clean energy technologies.

📚 PUBLICATION EXCELLENCE

With over 25 high-impact publications, Dr. Bariki has significantly enriched literature on multifunctional photocatalysts and green chemistry. His papers reflect a sophisticated understanding of charge migration mechanisms, material heterojunctions, and environmental decontamination strategies. His authorship often leads key projects, as seen in his corresponding author roles, emphasizing leadership in research dissemination.

NOTABLE PUBLICATION

Title: Facile synthesis and photocatalytic efficacy of UiO-66/CdIn₂S₄ nanocomposites with flowerlike 3D-microspheres towards aqueous phase decontamination of triclosan and H₂ evolution
Authors: R. Bariki, D. Majhi, K. Das, A. Behera, B.G. Mishra
Journal: Applied Catalysis B: Environmental 270, 118882 (2020)

Title: Plasmonic Ag nanoparticle decorated Bi₂O₃/CuBi₂O₄ photocatalyst for expeditious degradation of 17α-ethinylestradiol and Cr (VI) reduction: Insight into electron transfer
Authors: D. Majhi, A.K. Mishra, K. Das, R. Bariki, B.G. Mishra
Journal: Chemical Engineering Journal 413, 127506 (2021)

Title: Facile synthesis and application of CdS/Bi₂₀TiO₃₂/Bi₄Ti₃O₁₂ ternary heterostructure: a synergistic multi-heterojunction photocatalyst for enhanced endosulfan degradation and
Authors: K. Das, R. Bariki, D. Majhi, A. Mishra, K.K. Das, R. Dhiman, B.G. Mishra
Journal: Applied Catalysis B: Environmental 303, 120902 (2022)

Title: A facile reflux method for in situ fabrication of a non-cytotoxic Bi₂S₃/β-Bi₂O₃/ZnIn₂S₄ ternary photocatalyst: A novel dual Z-scheme system with enhanced
Authors: D. Majhi, K. Das, R. Bariki, S. Padhan, A. Mishra, R. Dhiman, P. Dash, et al.
Journal: Journal of Materials Chemistry A 8(41), 21729–21743 (2020)

Title: In-situ synthesis of structurally oriented hierarchical UiO-66 (–NH₂)/CdIn₂S₄/CaIn₂S₄ heterostructure with dual S-scheme engineering for photocatalytic renewable H₂ production
Authors: R. Bariki, S.K. Pradhan, S. Panda, S.K. Nayak, D. Majhi, K. Das, B.G. Mishra
Journal: Separation and Purification Technology 314, 123558 (2023)