Tag: Materials Leadership Award

Panagiotis Bousoulas | Materials Science | Research Excellence Award

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Assist. Prof. Dr. Panagiotis Bousoulas | Materials Science | Research Excellence Award

National Technical University of Athens | Greece

Assist. Prof. Dr. Panagiotis Bousoulas is an emerging scientific leader in the field of developmental biology and epigenetics, with a research program focused on understanding novel DNA and RNA modifications and their role in neural function, development, and disease. His academic foundation spans prestigious institutions, beginning with a BSc in Medical Genetics from the University of Leicester, followed by doctoral training at the University of Cambridge, UK, where he completed PhD rotations under globally recognized pioneers, including Sir John B. Gurdon, Sarah Bray, and Azim Surani. Prior to this, he studied Physics at the University of Stuttgart, Germany—a multidisciplinary background that contributes to his systems-level scientific approach. Dr. Bousoulas’ professional trajectory includes advanced postdoctoral research at major international institutions such as the Gurdon Institute (Cambridge), Yale University, and the Broad Institute/Harvard University, where he worked with Sir John B. Gurdon, Antonio Giraldez, and John Rinn—leading authorities in developmental biology and genomics. He currently serves as a Principal Investigator at the Chinese Institute for Brain Research (CIBR), where he leads an independent research group supported by multiple competitive funding awards, including the Beijing Natural Science Foundation, Human Frontiers Long-Term Fellowship, Isaac Newton Trust, and a major BBSRC project grant exceeding £830,000. His groundbreaking work contributed to the discovery of methylated deoxyadenosine (m6dA) in vertebrate genomes, reported in Koziol et al., 2015, which opened an entirely novel field in vertebrate epigenetics. His research continues to advance global understanding of how DNA and RNA chemical modifications regulate brain development and contribute to neurological disease, with potential applications in diagnostics and therapeutics. Recognized for excellence early in his career, Dr. Bousoulas has received awards from the AAAS Science Journal, Queen Elizabeth II, the Wellcome Trust, and Cambridge European Trust. His research has significant societal impact, contributing to improved understanding of molecular mechanisms underlying brain disorders and offering potential routes toward medical innovation.

Profile: Scopus | ORCID

Featured Publications

  • (2025). Closed-loop CBRAM crossbar system toward hardware acceleration of quantum algorithms. IEEE Transactions on Circuits and Systems

  • (2025). Low-power perovskite-based memristors enable fused reservoir computing and neuromorphic vision with highly accurate color perception.

  • (2025). A physics-based compact SPICE model emulating volatile and non-volatile switching patterns to heart arrhythmia detection.

  • (2025). Highly reliable perovskite-based memristors using Ag nanoparticles/FA₂PbI₄ junctions for enhanced memory and optoelectronic synaptic performance.

  • (2025). Low-power FA₂PbI₄/SiO₂ bilayer memristors with Pt nanoparticles exhibiting reconfigurable synaptic and neuron properties for compact optoelectronic neuromorphic systems.

Dongliang Wu | Materials Science | Research Excellence Award

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Dr. Dongliang Wu | Materials Science | Research Excellence Award

Shandong Institute of Petroleum and Chemical Technology | China

Dr. Dongliang Wu is an emerging materials scientist specializing in carbon fiber surface modification, interface engineering, and high-performance polymer composites. His research focuses on designing advanced interfacial structures that substantially enhance the mechanical and functional properties of carbon fiber–reinforced composites. Through the innovative use of polydopamine (PDA), cellulose nanofibers (CNF), carbon nanotubes (CNTs), and supramolecular polymers, Dr. Wu has developed a series of single and multi-scale interface architectures—ranging from flexible and dual-flexible systems to flexible–rigid hierarchical structures—that contribute significantly to understanding interfacial stress transfer, adhesion enhancement, and failure mechanisms in composite materials. Dr. Wu has produced a strong academic output with 21 Scopus-indexed publications, more than 410 citations, and an h-index of 9, reflecting the growing global influence of his research. His work appears in high-impact international journals such as Chemical Engineering Journal, Composites Science and Technology, Applied Surface Science, Journal of Colloid and Interface Science, and International Journal of Biological Macromolecules. These publications highlight his multidisciplinary approach integrating nanotechnology, biomimetic design, interfacial chemistry, and materials processing. He has contributed to several competitive scientific research projects, including provincial and municipal foundations that support technological innovation and early-career scientific advancement. His collaborative work with research groups in materials science, polymer engineering, and interface chemistry has strengthened the practical relevance and scientific rigor of his findings. The societal impact of Dr. Wu’s research lies in the development of stronger, more reliable, and multifunctional composite materials with applications in aerospace, automotive engineering, energy systems, and advanced manufacturing. By optimizing carbon fiber interfaces at molecular and nanoscale levels, his studies contribute to improving structural safety, lightweight design, and long-term durability in critical engineering sectors. With a rapidly expanding research portfolio and proven innovation capacity, Dr. Wu is positioned to make sustained contributions to global materials science and next-generation composite technologies.

Profile: Scopus 

Featured Publications

Wu, D., Yao, Z., Sun, X., Liu, X., Liu, L., Zhang, R., & Wang, C. (2022). Mussel-tailored carbon fiber/carbon nanotubes interface for elevated interfacial properties of carbon fiber/epoxy composites. Chemical Engineering Journal, 429, 132449.

Wu, D., Song, S., Han, Y., Ma, Q., Liu, L., Zhang, R., & Wang, M. (2022). Design of carbon fiber with nano accuracy for enrichment interface. Composites Science and Technology, 230, 109734.

Wu, D., Liu, L., Ma, Q., Dong, Q., Han, Y., Liu, L., Zhao, S., Zhang, R., & Wang, M. (2023). Biomimetic supramolecular polyurethane with sliding polyrotaxane and disulfide bonds for strain sensors with wide sensing range and self-healing capability. Journal of Colloid and Interface Science, 630, 909–920.

Wu, D., Xing, Y., Liu, L., Dong, Q., Wang, M., & Zhang, R. (2024). Structural design of “straw and clay” based on cellulose nanofiber/polydopamine and its interfacial stress dissipation mechanisms. International Journal of Biological Macromolecules, 283, 138040.

Wu, D., Sun, X., Liu, X., Liu, L., & Zhang, R. (2021). Simple-effective strategy for surface modification via annealing treatment polydopamine coating. Applied Surface Science, 567, 150813.

Filiz Keleş | Materials Science | Best Researcher Award

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Assist. Prof. Dr. Filiz Keleş | Materials Science | Best Researcher Award

Niğde Ömer Halisdemir University | Turkey

Assist. Prof. Dr. Filiz Keleş is a dedicated materials physicist whose research spans semiconductor nanostructures, thin films, and next-generation photovoltaic and optoelectronic devices, contributing to the advancement of sustainable energy and nanotechnology-driven applications. Her expertise integrates experimental thin-film deposition, nanorod-based device engineering, optical modeling, and semiconductor characterization, with a particular focus on GaN, Si, InGaN, CIGS, and perovskite systems that hold transformative potential for high-performance photodetectors and solar-energy technologies. Dr. Keleş has authored 13 peer-reviewed research papers, accumulating 73 citations and an h-index of 6, demonstrating a steadily growing scientific influence in solid-state physics and thin-film technology. She has contributed to multiple national-scale R&D projects, including TÜBİTAK-supported programs on CIGS thin-film development, monolithic tandem solar cells, and silicon purification, reflecting her ability to bridge fundamental physics with industrially relevant innovation. Her patent on flexible CIGS/perovskite tandem devices underscores her commitment to translating laboratory research into scalable, real-world solutions aligned with global clean-energy priorities. Beyond her research output, Dr. Keleş has collaborated with interdisciplinary teams across materials science, chemistry, and electrical engineering, fostering knowledge exchange and strengthening the scientific community’s understanding of advanced semiconductor processes. She actively contributes to academic development through teaching responsibilities in physics and materials science and the supervision of graduate research on optoelectronic device design and thin-film engineering. Her work carries meaningful societal impact by addressing key challenges in energy efficiency, device sustainability, and nanomaterial integration, supporting broader global objectives toward renewable energy transition and green-technology innovation. With a strong research portfolio, evolving citation impact, and clear scientific vision, Dr. Keleş continues to advance the frontier of semiconductor physics and remains positioned as a promising contributor to future breakthroughs in high-efficiency, low-cost photovoltaic and optoelectronic systems.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

Cansizoglu, M. F., Hamad, S. M., Norman, D. P., Keles, F., Badraddin, E., … (2015). PiN InGaN nanorod solar cells with high short-circuit current. Applied Physics Express, 8(4), 042302.

Keles, F., Cansizoglu, H., Badraddin, E. O., Brozak, M. P., Watanabe, F., … (2016). HIPS-GLAD core–shell nanorod array photodetectors with enhanced photocurrent and reduced dark current. Materials Research Express, 3(10), 105028.

Badradeen, E., Brozak, M., Keles, F., Al-Mayalee, K., & Karabacak, T. (2017). High performance flexible copper indium gallium selenide core–shell nanorod array photodetectors. Journal of Vacuum Science & Technology A, 35(3).

Keles, F., Cansizoglu, H., Brozak, M., Badraddin, E., & Karabacak, T. (2016). Conformal core–shell nanostructured photodetectors with enhanced photoresponsivity by high-pressure sputter deposition. MRS Advances, 1(28), 2045–2050.

Hamad, S. M., Norman, D. P., Chen, Q. Y., Keles, F., & Seo, H. W. (2013). Competitive In and Ga incorporations for InxGa1−xN (0.29 < x < 0.36) nanorods grown at a moderate temperature. AIP Advances, 3(7).

Sayan Banik | Materials Science | Best Researcher Award

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Mr. Sayan Banik | Materials Science | Best Researcher Award

National Institute of Science Education and Research | India

Sayan Banik is a Senior Research Fellow at the School of Physical Sciences, National Institute of Science Education and Research (NISER), where he specializes in theoretical condensed matter physics with a focus on topological magnetism, multiscale materials modeling, and superconducting hybrid systems. His research spans first-principles electronic structure calculations, atomistic spin simulations, micromagnetic modeling, and Bogoliubov–de Gennes–based superconductivity studies, enabling a comprehensive understanding of emergent magnetic textures such as skyrmions, antiskyrmions, and topological soliton lattices. He has developed expertise in state-of-the-art computational tools including JUKKR, FLEUR, VASP, SPIRIT, MUMAX3, and custom tight-binding codes, supported by strong programming proficiency in Python, C++, Fortran, and scientific visualization environments. Sayan’s contributions include multiple high-impact publications in internationally recognized journals such as Physical Review B (Letters) and Advanced Science, where his works on noncollinear magnetism, skyrmion-antiskyrmion phases, and topological superconductivity have attracted increasing scholarly attention. His collaborative research engagements extend to the Peter Grünberg Institute, Forschungszentrum Jülich, working with eminent scientists in quantum condensed matter theory. His academic achievements are further supported by competitive fellowships, including the Junior/Senior Research Fellowship of the Department of Atomic Energy and the INSPIRE Scholarship of the Department of Science and Technology. He has also qualified multiple national-level examinations such as NET, GATE, JEST, JAM, and NGPE. Beyond research publications, Sayan has actively contributed to the scientific community through conference talks, poster presentations, participation in international schools, and teaching assistance roles in computational physics and laboratory courses. His work contributes to advancing theoretical frameworks that support future innovations in spintronics, quantum materials, and hybrid superconducting devices, offering long-term societal impact through potential applications in energy-efficient information technologies and quantum computing platforms. With a strong foundation in theory, expanding collaborations, and a steadily growing research profile, Sayan Banik represents a promising early-career researcher poised for significant contributions to next-generation condensed matter physics.

Profiles: ORCID | Google Scholar

Featured Publications

Chatterjee, P., Banik, S., Bera, S., Ghosh, A. K., Pradhan, S., Saha, A., … (2024). Topological superconductivity by engineering noncollinear magnetism in magnet/superconductor heterostructures: A realistic prescription for the two-dimensional Kitaev model. Physical Review B, 109(12), L121301.

Banik, S., & Nandy, A. K. (2025). Skyrmion–antiskyrmion lattice: A net-zero topological phase in low-symmetry frustrated chiral magnets. Physical Review B, 112(14), L140404.

Banik, S., Kiselev, N. S., & Nandy, A. K. (2025). Paradoxical topological soliton lattice in anisotropic frustrated chiral magnets. Advanced Science, e14568.

Yanli Wang | Materials Science | Best Researcher Award

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Prof. Yanli Wang | Materials Science | Best Researcher Award

Hainan Medical University, China

Prof. Wang Yanli is a distinguished researcher and academic leader specializing in precision-targeted cancer research, nanochemistry, molecular imaging, and translational medicine. After completing his doctoral studies at the Institute of Nanochemistry and Biology, Shanghai University, in 2010, he has held a series of progressive academic and administrative positions, including director of the Center for Precision Targeted Cancer Research, dean of the Hu Jinhua Institute of Precision Health Education, and, most recently, professor at Hainan University and dean of the School of Pharmacy at Hainan Medical University. Prof. Wang has conducted visiting research at globally renowned institutions, including Clemson University and Harvard University, enhancing his international collaborations and fostering cross-border knowledge exchange. His research portfolio is extensive and impactful, encompassing over 56 SCI-indexed publications with 2,764 citations and an h-index of 25, reflecting both the quality and influence of his work. He has secured multiple competitive national-level grants, including funding from the National Natural Science Foundation of China for Excellent Young Scholars and the National Outstanding Young Scholars Fund, leading six major projects in cancer diagnostics, molecular imaging, and nanotechnology applications. Prof. Wang has also applied for 15 patents and contributed to the authorship and editing of monographs, underscoring his commitment to innovation and knowledge dissemination. Prof. Wang’s leadership extends beyond research. He serves in numerous professional and advisory capacities, including as an expert member of the Big Health Committee of the United Nations World Silk Road Forum and as director or member of multiple national and regional medical imaging and oncology committees. His work has tangible societal impact, advancing precision oncology, improving molecular imaging technologies, and contributing to public health strategies. Recognized with awards such as the Yangtze River Delta Most Potential Technology Trading Award and the International Association for Advanced Materials Young Scientist Award, Prof. Wang continues to bridge fundamental research, translational applications, and industry innovation, making significant contributions to science, healthcare, and global biomedical advancements.

Profiles: Scopus | ORCID

Featured Publications

  1. Li, Y., Zhang, Y., Li, C., Chen, G., Muhammad, P., Yao, Y., Gao, L., Liu, Z., & Wang, Y. (2025, October). Advanced cancer immunotherapy via SMARCAL1 blockade using a glucose‐responsive CRISPR nanovaccine. Advanced Science.

  2. Tang, T., Chen, J., Zhang, J., Pan, P., Jiang, J., Hu, C., He, Y., Li, C., Zhang, J., & Wang, Y. (2025, August). High concentrations of fluorescent nanoprobes delayed Oryzias melastigma embryo hatching by modulating respiratory and metabolic pathways. VIEW.

  3. Muhammad, P., Zada, A., Rashid, J., Hanif, S., Gao, Y., Li, C., Li, Y., Fan, K., & Wang, Y. (2024, July). Defect engineering in nanocatalysts: From design and synthesis to applications. Advanced Functional Materials.

  4. He, W., Zhang, J., Ju, J., Wu, Y., Zhang, Y., Zhan, L., Li, C., & Wang, Y. (2023, November). Preparation, characterization, and evaluation of the antitumor effect of kaempferol nanosuspensions. Drug Delivery and Translational Research.

  5. Qiu, L., Alqahtani, B. A., Li, C., He, W., Yin, X., Zhan, L., Zhang, J., & Wang, Y. (2023, August 2). Changes in diet, exercise and psychology of the quarantined population during the COVID-19 outbreak in Shanghai. PLOS ONE.

Prof. Wang Yanli’s work advances precision-targeted cancer research and molecular imaging, driving innovation in diagnostics and therapeutics. His research bridges fundamental science and translational applications, enhancing healthcare outcomes, promoting biomedical technology development, and supporting global health initiatives.

Xue Yu | Materials Science | Best Researcher Award

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Ms. Xue Yu | Materials Science | Best Researcher Award

Chengdu University, China

Professor Xue Yu, PhD, is a leading scholar in materials science and mechanical engineering, specializing in advanced functional materials, luminescent nanocrystals, and optoelectronic applications. She earned her PhD from Lanzhou University in 2010 and an MS from Henan University in 2007. Currently, she serves as Professor at the School of Mechanical Engineering, Institute for Advanced Materials, Chengdu University, and Deputy Director of its Graduate Office. She has previously held key academic positions at Kunming University of Science and Technology and completed a visiting scholar tenure at New Mexico State University, USA. Professor Yu’s research focuses on in vivo mechanical signal sensing, nanocrystal upconversion, long-persistent luminescence, perovskite scintillators, and the development of high-performance optoelectronic and imaging materials. Her work has yielded over 60 peer-reviewed publications in prestigious international journals such as Advanced Materials, ACS Nano, Advanced Optical Materials, and Chemical Engineering Journal, accumulating more than 3,000 citations with an h-index of 34. She has led multiple national research grants exceeding 3 million CNY, including projects supported by the National Natural Science Foundation of China and talent development programs such as the Rongpiao Plan and Tianfu Emei Plan. Professor Yu has also been recognized with numerous scientific awards, including the First Prize in Natural Science of Yunnan Province (2019) and Third Prize of Natural Science (2020), alongside multiple student guidance and innovation awards at national competitions. Her inventive contributions include patents in perovskite nanowire arrays, near-infrared fluorescent materials, and multimodal luminescent systems. Beyond publications and patents, Professor Yu actively mentors emerging researchers, guiding projects in advanced luminescent materials, stress imaging, and optoelectronic device development. Her work not only advances fundamental understanding of defect-engineered nanomaterials and luminescence mechanisms but also drives societal impact through innovations in biomedical imaging, energy-efficient lighting, and high-performance sensors. With extensive collaborations both nationally and internationally, Professor Yu’s research integrates materials science, photonics, and applied engineering, establishing her as a prominent figure whose scientific contributions are advancing technology and addressing critical challenges in imaging, sensing, and sustainable material development.

Profiles: Scopus | ORCID

Featured Publications

  1. Fan, X., Zeng, T., Zeng, C., Zeng, G., Xiong, F., Gao, R., Zhang, Y., Hao, X., Hu, A., Yu, X., et al. (2025). Cuprous halides scintillator via anion‐substitution strategy for X‐ray dynamic imaging. Laser & Photonics Reviews.

  2. Wang, T., Sun, J., Teng, Z., Yao, S., Yuan, J., Han, L., Mu, D., Song, H., Yu, X., Xu, X. (2025). Near‐infrared emission perovskites for multifunctional bioimaging. Small Science.

  3. Bu, W., Wang, T., Wang, Y., Huang, W., Guo, L., Yue, Y., Zhu, X., Xiao, J., Yu, X. (2025). Near‐infrared mechanoluminescence of Gd3Ga5O12: Cr3+, La3+ for biological stress imaging. Laser & Photonics Reviews.

  4. Hu, A., Hou, L., Yue, Y., Yu, S. F., Yu, X., Wang, T. (2025). Ultraelastic lead halide perovskite films via direct laser patterning. ACS Nano.

  5. Zhu, N., Wang, T., Guo, L., Zhu, X., Bu, W., Yue, Y., Yu, X. (2024). Multimodal dynamic luminescence of self-activated Na2CaGe2O6 phosphor via defect manipulation. CrystEngComm.

Ms. Xue Yu’s pioneering work in luminescent nanomaterials and optoelectronic devices bridges fundamental science and practical innovation, driving advancements in biomedical imaging, stress sensing, and energy-efficient lighting technologies. Her research contributes significantly to sustainable material development and fosters global innovation in next-generation photonic and electronic systems.

Mohamed Sheik Sirajuddeen Mohamed Abdullah | Materials Science | Best Researcher Award

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Prof. Mohamed Sheik Sirajuddeen Mohamed Abdullah | Materials Science | Best Researcher Award

B.S.Abdur Rahman Crescent Institute of Science and Technology, India

Prof. Mohamed Sheik Sirajuddeen Mohamed Abdullah is an accomplished Associate Professor in the Department of Physics, specializing in Computational Materials Science, with a distinguished career spanning over 21 years in teaching and 10 years in research. He holds a Ph.D. in Condensed Matter Physics from Anna University, Chennai, an M.Phil. in Physics from Manonmaniam Sundaranar University, an M.Sc. in Physics from Bharathidasan University, and a B.Sc. in Physics from the University of Madras. Prof. Sirajuddeen has made significant contributions to computational materials science through advanced simulations, density functional theory (DFT), and nuclear materials analysis, focusing on the structural, electronic, optical, elastic, and thermodynamic properties of novel materials including perovskites, lead-free compounds, and spintronic systems for optoelectronic and energy applications. His professional experience includes designing advanced physics curricula, establishing computational labs, mentoring Ph.D. scholars, leading department accreditations, and conducting corporate technical training programs. His research interests encompass computational modeling of materials, nuclear security, sustainable energy technologies, and AI-driven materials engineering. Prof. Sirajuddeen’s technical skills include proficiency in Fortran, C, FP-LAPW, TB-mBJ methods, VASP codes, Materials Studio, and Linux/Ubuntu systems, with additional expertise in research article review and nuclear safety certifications from the IAEA. He has published 38 research documents, garnering 339 citations with an h-index of 11, reflecting his influence and impact in the field. Prof. Sirajuddeen’s awards and honors include the Excellent Teaching Award (2019), Best Paper Award at Anna University, and multiple editorial board memberships. He has actively participated in international workshops, including ICTP-IAEA programs, and contributed to developing global elective courses on nuclear advocacy and materials science. In conclusion, Prof. Mohamed Sheik Sirajuddeen combines outstanding teaching, research excellence, and international engagement, positioning him as a leading figure in computational materials science with strong potential to advance sustainable technologies, nuclear security, and innovative materials research globally.

Profiles: Scopus | ORCID | LinkedIn

Featured Publications

  1. Ajay, G., Ashwin, V., & Sheik Sirajuddeen, M. M. (2025, October). DFT-based investigation on novel lead-free inorganic cubic halide double perovskite Cs₂LiInX₆ (X = Br and I) for energy harvesting device applications. Computational Condensed Matter, 5, e01155.

  2. Hussain, M. M. S., Mohamed, S. B., & Sheik Sirajuddeen, M. M. (2025, October). Pressure induced DFT study on structural, electronic, optical, and thermodynamic properties of lead free InXF₃ (X = Sr and Ba) for optoelectronic applications. Computational Condensed Matter, 5, e01077.

  3. Ashwin, V., Sirajuddeen, M. M. S., & Ajay, G. (2024, September). Dynamical stability, electronic and optical properties of AcAlO₃ perovskite using mBJ and hybrid functionals: A DFT approach. Computational Condensed Matter, 4, e00930.

  4. Kaleemullah, N. S., Mohamed, S. B., Ramakrishnan, P., Ashwin, V., & Sheik Sirajuddeen, M. M. (2024, September). Study of optical responsivity and electronic properties of ternary halide perovskite semiconductors – CaKI₃ and CaRbI₃ for optoelectronic applications: A DFT approach. Computational Condensed Matter, 4, e00939.

  5. Hussain, M. M. S., Kaleemullah, N. S., Ajay, G., & Sheik Sirajuddeen, M. M. (2024, September 1). A DFT study on structural, electronic, and optical properties of cubic perovskite semiconductors InXF₃ (X = Be and Ca) for optoelectronic applications. Modelling and Simulation in Materials Science and Engineering, 32, ad5a2c.

Prof. Mohamed Sheik Sirajuddeen Mohamed Abdullah work advances science and industry by leveraging computational materials science and nuclear research to develop innovative materials and sustainable energy technologies, while promoting global nuclear safety and fostering international scientific collaboration. His research bridges fundamental physics with practical applications, driving technological innovation and societal impact worldwide.

Shahzad Ahmed | Materials Science | Best Researcher Award

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Mr. Shahzad Ahmed | Materials Science | Best Researcher Award

Indian Institute of Technology Jodhpur, India

Mr. Shahzad Ahmed is a distinguished researcher and Prime Minister’s Research Fellow (PMRF) pursuing his Ph.D. in the Department of Materials Engineering at the Indian Institute of Technology (IIT) Jodhpur, India, with a stellar CGPA of 9.54. He holds an M.Tech in Nanotechnology (Gold Medalist, CGPA 9.48) from Jamia Millia Islamia, an M.Sc. in Physics from the University of Delhi, and a B.Sc. (Hons) in Physics from Ramjas College, University of Delhi. His professional and international research experience includes serving as a Visiting Scholar at the State University of New York at Buffalo (USA) and as a Researcher at the National Yang Ming Chiao Tung University (Taiwan), where he worked on nanostructured materials and advanced sensor technologies. His research interests lie in nanomaterials and nanotechnology, particularly borophene, graphene, MoS₂, and other low-dimensional materials, focusing on electrochemical-based sensors, biosensors, and thin-film fabrication for health and food monitoring applications. Mr. Ahmed possesses strong technical and analytical expertise in electrochemical analysis (CV, EIS, DPV), nanoparticle synthesis, CVD/PVD coating, photolithography, and advanced material characterization using SEM, Raman, FTIR, and UV-Vis spectroscopy. He has published more than 36 peer-reviewed papers, accumulating 872 citations and an h-index of 17, along with a U.S. Patent on borophene tubes. His remarkable achievements include securing the prestigious PMRF Fellowship, qualifying GATE (AIR 1839), and completing specialized training in Nano- and Microfabrication at National Tsing Hua University, Taiwan. He is also an active reviewer for more than twenty international journals, reflecting his professional recognition in the global scientific community. In conclusion, Mr. Shahzad Ahmed’s academic excellence, innovative research, and multidisciplinary skills make him a promising young scientist poised to contribute significantly to the advancement of nanotechnology, materials science, and sensor innovation on an international scale.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | Staff Page

Featured Publications

Khan, A., Islam, S. M., Ahmed, S., Kumar, R. R., Habib, M. R., Huang, K., Hu, M., Yu, X., … (2018). Direct CVD growth of graphene on technologically important dielectric and semiconducting substrates. Advanced Science, 5(11), 1800050.

Ahmed, S., Ansari, A., Haidyrah, A. S., Chaudhary, A. A., Imran, M., & Khan, A. (2022). Hierarchical molecularly imprinted inverse opal-based platforms for highly selective and sensitive determination of histamine. ACS Applied Polymer Materials, 4(4), 2783–2793.

Imran, M., Ahmed, S., Abdullah, A. Z., Hakami, J., Chaudhary, A. A., Rudayni, H. A., … (2023). Nanostructured material‐based optical and electrochemical detection of amoxicillin antibiotic. Luminescence, 38(7), 1064–1086.

Khan, A., Ahmed, S., Sun, B. Y., Chen, Y. C., Chuang, W. T., Chan, Y. H., Gupta, D., … (2022). Self-healable and anti-freezing ion conducting hydrogel-based artificial bioelectronic tongue sensing toward astringent and bitter tastes. Biosensors and Bioelectronics, 198, 113811.

Khan, A., Cong, J., Kumar, R. R., Ahmed, S., Yang, D., & Yu, X. (2022). Chemical vapor deposition of graphene on self-limited SiC interfacial layers formed on silicon substrates for heterojunction devices. ACS Applied Nano Materials, 5(12), 17544–17555.

Mr. Shahzad Ahmed’s pioneering research on advanced nanomaterials and electrochemical sensors is driving innovation in sustainable healthcare, food safety, and environmental monitoring. His work bridges the gap between scientific discovery and real-world application, fostering global progress in nanotechnology and smart sensing solutions for a healthier, safer, and more sustainable future.

Yaping Wu | Materials Science | Best Researcher Award

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Prof. Dr. Yaping Wu | Materials Science | Best Researcher Award

Xiamen University, China

Professor Dr. Yaping Wu is a distinguished physicist at the Department of Physics, Xiamen University, China, with expertise in wide-bandgap semiconductor optoelectronic devices, quantum structures, graphene and two-dimensional materials, as well as surface interface physics and spintronics. He earned his B.Sc. in Physics from Xiamen University in 2006 and his Ph.D. in Microelectronics and Solid-State Electronics in 2012, including joint doctoral training at the University of Texas at Austin, USA. Since 2012, he has progressed from assistant professor to associate professor and currently serves as full professor at Xiamen University, demonstrating strong academic leadership and mentorship. His research interests encompass the growth and application of novel quantum structures, spin injection and regulation in nitride semiconductors, heterostructures of 2D materials, and chiral photonic quantum devices. Professor Wu possesses advanced research skills in device fabrication, spintronic and optoelectronic characterization, and integration of 2D material heterostructures. He has led multiple national and provincial projects, including NSFC Excellent Young Scientists Fund and several General Program grants, reflecting his leadership in pioneering semiconductor and quantum device research. His scholarly contributions include over 127 publications in high-impact journals such as Nature Electronics, Advanced Materials, Nano Letters, and ACS Nano, with 3,994 citations and an h-index of 23. He also holds numerous patents on spintronic devices, optical rotation systems, and electrically controllable quantum devices. Professor Wu’s awards and honors include Outstanding Research Achievement from NSFC, Top 10 Research Advances in China’s Semiconductor Science and Technology, multiple national teaching and supervision awards, and recognition as a high-level talent in Fujian Province and Xiamen City. With a proven record of high-impact research, innovation, mentorship, and international collaboration, Professor Wu is positioned to continue advancing cutting-edge developments in semiconductor physics, optoelectronics, and 2D quantum materials, fostering both scientific breakthroughs and the next generation of researchers globally.

Profile: Scopus

Featured Publications

Wu, X., Li, X., Kang, W., Zhang, X., Chen, L., Zhong, Z., Zhou, Y., Åkerman, J., Wu, Y., Zhang, R., & Kang, J. (2023). Topology-induced chiral photon emission from a large-scale meron lattice. Nature Electronics, 6(7), 516–524.

Wu, S., Wu, Q., Zhang, Y., Liu, M., Zhang, C., Wei, Y., Gao, Y., Xu, F., Zhang, C., Cao, Y., Zheng, X., Wu, Y., Wu, Z., Li, X., & Kang, J. (2025). Giant and anisotropic spin relaxation time in van der Waals GeSe with gate-tunability. Advanced Materials, 37(34), e2501618.

Cheng, A., Li, Z., Huang, F., Zhang, Y., Zhang, C., Xu, F., Zheng, X., Li, X., Wu, Z., Wu, Y., & Kang, J. (2025). Plasma-mediated polarity modulation in 2D ReS2 memristors for bio-inspired cascaded memristive architecture with stability-plasticity synergy. Materials Today. Advance online publication.

Liu, H., Zhang, Z., Zhang, C., Li, X., Zhang, C., Xu, F., Wu, Y., Wu, Z., & Kang, J. (2024). Simultaneously regulated highly polarized and long-lived valley excitons in WSe2/GaN heterostructures. Nano Letters, 24(6), 1851–1858.

Wu, X., Gong, B., Kang, W., Chen, L., Li, X., Wu, Y., & Kang, J. (2025). Orbital coupling and spin textures of Fe/Pd thin films grown on Si substrate with high magnetic fields. Advanced Science, 12(23), e2417810.

Prof. Dr. Yaping Wu’s pioneering research in wide-bandgap semiconductors, quantum structures, and 2D materials drives advances in next-generation optoelectronic and spintronic devices, enabling high-performance communication, energy-efficient electronics, and transformative technologies that impact science, industry, and global innovation.

Afsar Ahmed | Materials Science | Best Researcher Award

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Dr. Afsar Ahmed | Materials Science | Best Researcher Award

Saha Institute of Nuclear Physics, India

Dr. Afsar Ahmed is a promising researcher in condensed matter physics, currently pursuing his Ph.D. at the Condensed Matter Physics Division, Saha Institute of Nuclear Physics, Kolkata (2019–2025) under the guidance of Prof. Indranil Das. He completed his M.Sc. (2017) and B.Sc. (2015) in Physics from Aligarh Muslim University, India, both with first-class distinction. His professional experience encompasses extensive research in magnetic materials, magnetocaloric effects, magnetotransport phenomena, anomalous and topological Hall effects, spintronics, and skyrmions, with a Ph.D. thesis focused on non-collinear spin-induced magnetic and transport properties in intermetallic compounds, exploring the coexistence of real-space and momentum-space topologies in systems like inverse Heusler alloys, β-Mn, and layered magnets. Dr. Ahmed has authored 12 publications in reputed journals including Advanced Functional Materials, Physical Review B, and Journal of Physics: Condensed Matter, with 32 citations and an h-index of 3, and presented his work at leading national conferences such as DAESSPS, QMAT, SMS, and ICBEC. His research skills include polycrystalline and single-crystal sample preparation, thin-film deposition (PLD, sputtering), device fabrication, X-ray diffraction (Rigaku TTRAX-III), TEM-EDX, SQUID-VSM, PPMS, and customized cryogenic setups (9 T, 2 K), supported by proficiency in Origin, FullProf, Vesta, Python, LabVIEW, LaTeX, and Fortran-77. Dr. Ahmed has been recognized through merit scholarships, and has qualified competitive exams including GATE, NET, JEST, and WBSET. His awards and honors highlight his academic excellence and commitment to research. With a strong academic foundation, robust publication record, diverse research skills, and active engagement in the scientific community, Dr. Afsar Ahmed is well-positioned to advance impactful research in quantum and topological materials, contribute to international collaborations, and mentor future generations of scientists.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

Ahmed, A., Mazumdar, D., Das, K., & Das, I. (2022). A comparative study of the magnetic and magnetocaloric effect of polycrystalline Gd0.9Y0.1MnO3 and Gd0.7Y0.3MnO3 compounds: Influence of Y-ions on the magnetic state of GdMnO3. Journal of Magnetism and Magnetic Materials, 551, 169133.

Bhattacharya, A., Habib, M. R., Ahmed, A., Satpati, B., DuttaGupta, S., & Dasgupta, I. (2024). Spin-valve-like magnetoresistance and anomalous Hall effect in magnetic Weyl metal. Physical Review B, 110(1), 014417.

Bhattacharya, A., Ahmed, A., DuttaGupta, S., & Das, I. (2023). Critical behavior and phase diagram of skyrmion-hosting material Co3.6Fe4.4Zn8Mn4 probed by anomalous Hall effect. Journal of Alloys and Compounds, 960, 170274.

Bhattacharya, A., PC, S., Ahmed, A., Kurebayashi, D., Tretiakov, O. A., Satpati, B., … (2025). Giant topological Hall effect in magnetic Weyl metal Mn2Pd0.5Ir0.5Sn. Advanced Functional Materials, 35(17), 2424841.

Ahmed, A., Das, K., & Das, I. (2024). Large magnetocaloric effect and giant magnetoresistance in rare earth based intermetallic compound ErAl3: Construction of magnetic phase diagram. Journal of Physics: Condensed Matter. Advance online publication.

Dr. Afsar Ahmed’s research on topological and magnetic materials advances fundamental understanding of quantum phenomena, enabling the development of next-generation spintronic devices and energy-efficient technologies, while fostering innovations that bridge materials science, industry applications, and global scientific progress.