Tag: Breakthrough Materials Research Award

Mehdi Rafizadeh | Materials Science | Best Research Article Award

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Prof. Dr. Mehdi Rafizadeh | Materials Science | Best Research Article Award

Amirkabir University of Technology, Iran

Prof. Dr. Mehdi Rafizadeh, is a distinguished Professor in the Department of Polymer Engineering and Color Technology at Amirkabir University of Technology, Iran, where he has established himself as a leading authority in polymer science and chemical engineering. He earned his B.Sc. (1989) and M.Sc. (1991) in Chemical Engineering from Amirkabir University of Technology, followed by a Ph.D. in Chemical Engineering (Polymer) from McGill University, Montreal, Canada, in 1997. With over three decades of academic and research excellence, his professional experience spans teaching, supervising graduate students, conducting applied research, and leading industrial projects that bridge the gap between academia and industry. His research interests focus on polymer engineering, materials science, color technology, sustainable chemical processes, and industrial applications of advanced polymeric materials. He has an impressive scholarly record, with 83 peer-reviewed journal publications, 163 conference papers, two books, and 12 industrial research projects, along with a Scopus profile showing 92 indexed documents, 1,161 citations, and an h-index of 14, which testify to his global academic impact. His research skills encompass polymer synthesis and characterization, advanced chemical engineering methodologies, industrial process optimization, and interdisciplinary collaboration, making him a highly versatile researcher and mentor. Throughout his career, Prof. Rafizadeh has been recognized with several honors for his contributions to polymer research and his dedication to academic excellence, including leadership roles in academic platforms and involvement in international scientific communities. His achievements reflect a commitment not only to advancing scientific knowledge but also to mentoring young researchers, promoting industrial innovation, and contributing to the broader scientific community. In conclusion, Prof. Dr. Mehdi Rafizadeh’s exceptional academic background, impactful research contributions, strong international collaborations, and dedication to education and industrial development make him a highly respected scholar and deserving candidate for recognition in the global scientific community.

Profile: Scopus | ORCID | Google Scholar

Featured Publications

Neghlani, P. K., Rafizadeh, M., & Taromi, F. A. (2011). Preparation of aminated-polyacrylonitrile nanofiber membranes for the adsorption of metal ions: Comparison with microfibers. Journal of Hazardous Materials, 186(1), 182–189.

Fallahi, D., Rafizadeh, M., Mohammadi, N., & Vahidi, B. (2008). Effect of applied voltage on jet electric current and flow rate in electrospinning of polyacrylonitrile solutions. Polymer International, 57(12), 1363–1368.

Rafizadeh, M., Patterson, W. I., & Kamal, M. R. (1996). Physically-based model of thermoplastics injection molding for control applications. International Polymer Processing, 11(4), 352–362.

Zahedi, A. R., Rafizadeh, M., & Ghafarian, S. R. (2009). Unsaturated polyester resin via chemical recycling of off‐grade poly(ethylene terephthalate). Polymer International, 58(9), 1084–1091.

Ahmadi, R., Alivand, M. S., Tehrani, N. H. M. H., Ardjmand, M., Rashidi, A., & Rafizadeh, M. (2021). Preparation of fiber-like nanoporous carbon from jute thread waste for superior CO₂ and H₂S removal from natural gas: Experimental and DFT study. Chemical Engineering Journal, 415, 129076.

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

Feng Wang | Materials Science | Best Researcher Award

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Prof. Feng Wang | Materials Science | Best Researcher Award

Professor at Southwest University, China

Feng Wang is a Professor at the Biological Research Center of Southwest University, China, specializing in molecular biology, genetic engineering, and biomaterials. He earned his Ph.D. in Biochemistry and Molecular Biology from Southwest University in 2014. Wang’s research focuses on genetic modification of silkworms to produce functional biomaterials and recombinant proteins for biomedical applications, such as tissue engineering and drug delivery. His work on genome editing using CRISPR/Cas9 and other techniques has led to significant advancements in bio-functional silk production. Wang has published extensively in high-impact journals, contributing to the fields of biotechnology and bioengineering. He has also held roles as a visiting scholar and postdoctoral researcher at various institutions. His groundbreaking research continues to make valuable contributions to the development of innovative medical technologies.

Professional Profile

Education and Work Experience:

Feng Wang completed his undergraduate degree in Bioengineering at the College of Life Science, Southwest University, Chongqing, China, graduating in 2008. He pursued advanced studies at the same institution, earning a Ph.D. in Biochemistry and Molecular Biology from the State Key Laboratory of Silkworm Genome Biology, Southwest University, in 2014. During his academic career, he has held several important positions. He became an Associate Professor at Southwest University in 2018, and in 2023, he was promoted to a full Professor at the Biological Research Center of the university. Wang has also gained valuable international experience as a visiting scholar at Tufts University, USA, from 2018 to 2019. Before this, he served as a research associate and postdoctoral researcher at Southwest University’s College of Biotechnology, contributing significantly to the fields of molecular biology and biotechnology. His career trajectory showcases his growing expertise and leadership in the scientific community, particularly in genetic engineering and biomaterial development, where he continues to make notable contributions to both academia and industry.

Research Interests and Contributions:

Feng Wang’s primary research interests focus on the genetic modification of silkworms and other insect species to enhance functional biomaterials. He specializes in genome editing techniques such as CRISPR/Cas9, TALEN, and ZFN to regulate gene expression and modify silkworm genomes for various applications. Wang has pioneered the use of genetically engineered silkworm spun silk as a potential biomaterial for biomedical purposes, including tissue engineering. His work on producing recombinant pharmaceutical proteins, such as growth factors, human lactoferrin, and human serum albumin, within silkworms, has significant implications for cost-effective, large-scale production of valuable biomolecules. Wang’s research also explores the use of silkworm silk glands as bioreactors for producing proteins with therapeutic applications. His recent studies emphasize the development of silk-based materials for tissue regeneration and other medical uses, demonstrating his ability to bridge molecular biology, biotechnology, and material science. His interdisciplinary work continues to advance the potential of silkworms in producing bio-functional materials with wide-ranging biomedical applications.

Publications and Achievements:

Feng Wang has authored and co-authored numerous high-impact publications in renowned scientific journals. His work spans diverse topics, with a particular focus on genetic engineering, biomaterials, and recombinant protein production. Notable recent publications include articles in Advanced Materials, Biomaterials, and Insect Science, with research exploring the production of functional silk fibroin-based biomaterials and the application of transgenic silkworms for large-scale recombinant protein production. Wang has contributed significantly to advancements in silk engineering, including the fabrication of silk sericin hydrogels for tissue repair and the development of silk-based systems for the delivery of therapeutic proteins. His collaborative approach has also led to joint publications with international researchers, further expanding the impact of his research. Wang’s scientific contributions have received global recognition, and his work continues to inspire advancements in bioengineering and biotechnology. He is also an active member of various research networks and collaborations, facilitating the exchange of knowledge and ideas across the global scientific community. With a growing body of work, his research continues to address pressing challenges in biomedical applications, making him a recognized leader in his field.

Strengths for the Award:

Feng Wang’s research is highly innovative and interdisciplinary, merging molecular biology, genetic engineering, and biomaterial science to address key challenges in biomedical applications. His expertise in genome editing, especially in transgenic silkworms, positions him as a leading figure in the development of functional biomaterials for medical use. Wang’s ability to apply cutting-edge techniques such as CRISPR/Cas9, TALEN, and ZFN for silkworm genetic modification has resulted in the creation of valuable materials, including recombinant pharmaceutical proteins and tissue-engineering scaffolds. His work in engineering silkworm spun silk to express functional proteins demonstrates both creativity and technical proficiency, allowing for the large-scale production of bio-functional biomaterials with significant medical potential. Wang’s leadership as an academic researcher and his extensive publication record, including high-impact journals with broad citations, further demonstrate his research excellence. His collaborative approach with both domestic and international research communities enhances the relevance and impact of his contributions. Overall, his continuous pursuit of innovative solutions for biomedical applications underscores his potential as a strong contender for the Best Researcher Award.

Areas for Improvement:

While Feng Wang has made significant contributions to his field, there are areas where his work can be further expanded to maximize its impact. One potential area for improvement is broadening the scope of his research to include more diverse applications of genetically modified silkworms, particularly in the context of personalized medicine or other innovative therapeutic strategies. Although Wang has focused heavily on protein production and tissue regeneration, there is room for exploring the potential of silkworm-based materials in other areas of biomedical engineering, such as drug delivery systems or diagnostic devices. Additionally, Wang could collaborate with industry partners to translate his findings into real-world applications more effectively. Strengthening his involvement in translational research could accelerate the commercialization of his discoveries, ensuring that his contributions have tangible benefits for society. Another area for improvement lies in the scalability and cost-efficiency of producing genetically modified silkworms and recombinant proteins, which could enhance the practicality and accessibility of his research outcomes. By addressing these challenges, Wang could further elevate the impact of his work and expand its application to broader sectors of healthcare.

Conclusion:

Feng Wang’s exceptional work in gene expression regulation, genome modification, and biomaterials development has significantly advanced the field of biotechnology, particularly in the context of biomedical applications. His pioneering research in genetically engineered silkworms has led to the creation of bio-functional silks that can be used in tissue engineering and the production of therapeutic proteins. With a proven track record of high-impact publications, international collaborations, and continuous innovation, Wang is a leading figure in his field. While there are areas where his research can expand, particularly in translating his findings into commercial applications and exploring additional biomedical uses for silkworm-derived materials, his contributions to science and technology are already substantial. Wang’s dedication to solving complex problems in biomedical engineering, combined with his technical expertise and visionary research, makes him a deserving candidate for the Best Researcher Award. His continued success and impact on the scientific community are promising, and his future work holds even greater potential for advancing healthcare technologies.

Publication Top Notes

  1. Title: Fabrication of a transforming growth factor β1 functionalized silk sericin hydrogel through genetical engineering to repair alveolar bone defects in rabbit
    • Authors: Wang, F., Ning, A., Sun, X., Ma, X., Xia, Q.
    • Year: 2025
  2. Title: Highly efficient expression of human extracellular superoxide dismutase (rhEcSOD) with ultraviolet-B-induced damage-resistance activity in transgenic silkworm cocoons
    • Authors: Wang, F., Wang, R., Zhong, D., Zhao, P., Xia, Q.
    • Year: 2024
    • Citations: 5
  3. Title: CRISPR/Cas9-Mediated Editing of BmEcKL1 Gene Sequence Affected Silk Gland Development of Silkworms (Bombyx mori)
    • Authors: Li, S., Lao, J., Sun, Y., Zhao, P., Xia, Q.
    • Year: 2024
    • Citations: 5
  4. Title: Antimicrobial mechanism of Limosilactobacillus fermentum SHY10 metabolites against pickle film-producing strain by metabolomic and transcriptomic analysis
    • Authors: Lian, Y., Luo, S., Song, J., Liu, K., Zhang, Y.
    • Year: 2024
  5. Title: An Efficient Biosynthetic System for Developing Functional Silk Fibroin-Based Biomaterials
    • Authors: Wang, F., Lei, H., Tian, C., Kaplan, D.L., Xia, Q.
    • Year: 2024
  6. Title: The different effects of molybdate on Hg(II) bio-methylation in aerobic and anaerobic bacteria
    • Authors: Wang, L., Liu, H., Wang, F., Wang, D., Shen, H.
    • Year: 2024
    • Citations: 1
  7. Title: Morusin shows potent antitumor activity for melanoma through apoptosis induction and proliferation inhibition
    • Authors: Liu, W., Ji, Y., Wang, F., Liu, Y., Cui, H.
    • Year: 2023
    • Citations: 3
  8. Title: Correction: Optimization of a 2A self-cleaving peptide-based multigene expression system for efficient expression of upstream and downstream genes in silkworm
    • Authors: Wang, Y., Wang, F., Xu, S., Zhao, P., Xia, Q.
    • Year: 2023

Souheyla MAMOUN | Materials Science | Best Researcher Award

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Assist. Prof. Dr. Souheyla MAMOUN | Materials Science | Best Researcher Award

Lecturer at Abou Beker BELKAID-Tlemcen University, Algeria

Souheyla Mamoun is a dedicated physicist specializing in materials physics, with extensive experience in academia and research. Since September 2014, following her doctoral training at the University of Lorraine, France, she has served at the Department of Physics, Faculty of Sciences, University Abou-Bakr Belkaid, Tlemcen. Her teaching, mentoring, and leadership roles reflect her passion for education and scientific advancement. With expertise in computational physics, renewable energy, and materials science, she has contributed significantly to her field, mentoring students and collaborating on impactful projects. Souheyla’s dedication to fostering academic excellence is evident through her active involvement in university life, teaching innovative courses, and authoring educational materials. She remains a vital contributor to the advancement of renewable energy research and physics education.

Professional Profile

Education

Souheyla Mamoun holds a Ph.D. in Physics of Materials from the University of Lorraine, Metz, France, completed before September 2014. Her doctoral research emphasized advanced materials and their applications, laying the foundation for her expertise in computational and renewable energy physics. She also holds a Master’s degree with a focus on photovoltaic systems and renewable energy, culminating in a published work on photovoltaic installations for isolated sites. Her strong educational background underscores her technical proficiency and dedication to scientific innovation.

Professional Experience

Souheyla Mamoun has been a faculty member at the University Abou-Bakr Belkaid since 2014, advancing to the role of Maître de Conférence B in 2015. Her teaching portfolio spans a wide range of physics courses, including electromagnetism, vibrations, and computational physics. She has supervised Master’s theses on topics like perovskite solar cells, photovoltaic systems, and nanocrystals, mentoring future researchers. Beyond teaching, Souheyla has served in leadership roles, such as President of the Pedagogical Coordination Committee and Coordinator of the Physics License program. Her contributions extend to organizing doctoral entrance exams and actively participating in educational and research committees, demonstrating her commitment to academic leadership.

Research Interests

Souheyla’s research interests lie at the intersection of computational physics, materials science, and renewable energy. Her focus includes numerical modeling of photovoltaic systems, study of nanostructures, and the impact of temperature on perovskite-based solar cells. She is also interested in hybrid organic-inorganic materials and their applications in advanced energy systems. Her research aims to optimize the efficiency and sustainability of renewable energy systems through innovative materials and computational techniques, contributing to the global transition toward greener technologies.

Research Skills

Souheyla Mamoun possesses a strong skill set in computational physics, numerical modeling, and renewable energy systems analysis. She is proficient in designing and evaluating photovoltaic systems, modeling I-V characteristics, and analyzing nanostructures using advanced computational tools. Her expertise includes preparing educational resources, mentoring research projects, and conducting comprehensive studies on energy materials. Her ability to translate theoretical physics into practical applications demonstrates her technical versatility and commitment to solving real-world energy challenges.

Awards and Honors

Souheyla’s accomplishments include publishing an educational textbook on electromagnetism, validated by the Scientific Council of her faculty in 2021, providing valuable resources to undergraduate students. Additionally, her Master’s thesis was adapted into a published book on photovoltaic systems by the European University Editions in 2013, showcasing her early contributions to renewable energy research. Her leadership roles, such as heading pedagogical committees and coordinating academic programs, further highlight her recognition as a committed educator and researcher.

Conclusion

Souheyla Mamoun is a highly skilled educator, researcher, and academic leader, deeply committed to advancing the field of materials physics and renewable energy. Her contributions to teaching, mentoring, and research reflect her passion for fostering scientific knowledge and innovation. Her expertise in computational physics and sustainable energy systems positions her as a valuable asset to her academic institution and the broader scientific community. With her dedication to excellence and impactful contributions, Souheyla Mamoun is a strong candidate for the Best Researcher Award, deserving recognition for her achievements and potential to drive further advancements in her field.

Publication Top Notes

  1. New eco-friendly Rb2PtI6 based double perovskite solar cells with high photovoltaic performance up to 26% efficiency: Numerical simulation
    • Authors: Mamoun, S., Merad, A.E.
    • Year: 2025
  2. Numerical simulation of highly photovoltaic efficiency of InGaN based solar cells with ZnO as window layer
    • Authors: Annab, N.,
    • Year: 2023
    • Citations:0
  3. Electronic, magnetic and optical properties of Cr and Fe doped ZnS and CdS diluted magnetic semiconductors: revised study within TB-mBJ potential
    • Authors: Ghazal, W., Mamoun, S., Kanoun, M.B., Goumri-Said, S., Merad, A.E.
    • Year: 2023
    • Citations: 5
  4. A Novel Theoretical Prediction of Electronic Structure, Phase Stability, and Half-Metallic Ferromagnetic Behavior of New Quaternary RhFeTiZ (Z = Al, Si) Heusler Alloys
    • Authors: Dergal, S., Doumi, B., Mokaddem, A., Mamoun, S., Merad, A.E.
    • Year: 2016
    • Citations: 5
  5. Energy band gap and optical properties of lithium niobate from ab initio calculations
    • Authors:Mamoun, S.
    • Year: 2013
    • Citations: 67