Khaja Hussain Shaik | Materials Science | Research Excellence Award

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Dr. Khaja Hussain Shaik | Materials Science | Research Excellence Award

Gyeongsang National University | South Korea

Dr. Khaja Hussain Shaik is a postdoctoral researcher in materials science and engineering with recognized expertise in nanomaterials, electrochemical energy storage, and optoelectronic materials. He holds doctoral training in electronic engineering with specialization in materials science, complemented by advanced education in chemistry, providing a strong interdisciplinary foundation. His professional experience spans postdoctoral and research scholar roles, contributing to high-impact projects in energy storage materials, nanosensors, and advanced functional materials, along with mentoring and laboratory leadership in academic environments. His research focuses on the design and synthesis of nanostructured oxides, carbon-based composites, and rare-earth-doped materials for supercapacitors, batteries, and photonic devices, resulting in a substantial portfolio of peer-reviewed publications with significant global citation impact. His contributions have advanced charge storage performance, device stability, and functional material design. He has received multiple prestigious research fellowships, dissertation and scholarship honors, and institutional recognitions for research excellence, reflecting sustained academic leadership, innovation, and strong potential for continued high-impact contributions to materials research.

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Featured Publications

 

Samiha Chaguetmi | Materials Science | Research Excellence Award

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Prof. Samiha Chaguetmi | Materials Science | Research Excellence Award

Professor | University of Skikda | Algeria

Prof. Samiha Chaguetmi, a Professor in the Physics Department at Skikda University in Algeria, is an expert in materials science with a specialization in semiconductor and metallic materials, thin films, and photoactive nanostructures. She holds advanced degrees in materials sciences and semiconductor physics, culminating in a doctoral qualification and subsequent habilitation focused on innovative material systems. Throughout her academic career, she has served as an assistant, lecturer, and senior academic, contributing extensively to teaching in areas such as structural analysis of materials, atomic physics, photovoltaic systems, and characterization methods. Her professional experience spans leadership in laboratory training programs, participation in international research collaborations, and active engagement in multidisciplinary projects involving hydrothermal synthesis, sol-gel processes, chemical bath deposition, magnetron sputtering, electrochemical methods, and advanced thin-film technologies. Prof. Chaguetmi’s research centers on photocatalysis, photo-electrochemical water splitting, and the development of nanostructured materials for energy and environmental applications, supported by expertise in SEM, TEM, XRD, FTIR, Raman spectroscopy, XPS, UV-VIS-DR spectrophotometry, and electrochemical impedance spectroscopy. She has contributed numerous publications to peer-reviewed journals and participated in scientific dissemination through conferences and collaborative programs across prominent international laboratories. Her achievements include recognition through a Research Excellence Award, alongside roles in academic service, mentoring, and scientific review activities. Prof. Chaguetmi is also engaged in professional development through repeated training missions in leading global research institutions, reinforcing her standing as a committed scholar whose work advances the understanding and application of functional materials for sustainable technologies.

Profiles: Scopus | ORCID

Featured Publications

1. Chaperman, L., Chaguetmi, S., Deng, B., Gam-Derrouich, S., Nowak, S., Mammeri, F., & Ammar, S. (2024). Novel synthesis route of plasmonic CuS quantum dots as efficient co-catalysts to TiO₂/Ti for light-assisted water splitting. Nanomaterials, 14(19), 1581.

2. Sobti, N., Chaguetmi, S., Amiour, L., Aouabdia, Y., & Saci, L. (2024). Photocatalytic properties of Mn₂O₃ nanoparticles synthesized via green chemistry method. Journal of Renewable Energies, 28(1).

3. Sobti, N., Chaguetmi, S., Achour, S., Gam-Derouich, S., Decorse, P., Nowak, S., & Ammar, S. (2024). Photoelectrochemical properties of TiO₂ nanofibers coated by copper oxide nanoparticles using sputtering and chemical bath deposition. Journal of Materials Science.

4. Momoli, R., Gandin, A., Ruffo, R., Chaguetmi, S., Mammeri, F., Abbotto, A., Manfredi, N., & Brusatin, G. (2021). Low dye content efficient dye-sensitized solar cells using carbon doped-titania paste from convenient green synthetic process. Inorganica Chimica Acta.

5. Sobti, N., Chaguetmi, S., Achour, S., Chaperman, L., Mammeri, F., & Ammar-Merah, S. (2021). Manganese oxide nanoparticles prepared by olive leaf extract-mediated wet chemistry and their supercapacitor properties. Solid State Sciences.

Prof. Samiha Chaguetmi envisions advancing the field of materials science through innovative research that drives sustainable energy solutions and strengthens the scientific understanding of functional nanomaterials. Her vision focuses on developing high-performance photocatalytic and photoelectrochemical systems, promoting environmentally responsible synthesis routes, and expanding collaborative research networks that bridge local and international scientific communities. She aims to contribute impactful knowledge, mentor future scientists, and support the development of advanced technologies that address global energy and environmental challenges.

Tun Naw Sut | Chemical Engineering | Best Researcher Award

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Dr. Tun Naw Sut | Chemical Engineering | Best Researcher Award

Sungkyunkwan University | South Korea

Dr. Tun Naw Sut is a postdoctoral fellow specializing in nanomedicine, biomimetic membranes, and bio-sensing technologies, recognized for his interdisciplinary expertise and impactful research contributions. He holds dual doctoral training in nanomedicine and chemical engineering, supported by prior qualifications in materials science and biomedical engineering, forming a strong foundation for his work at the interface of engineering, biotechnology, and nanomaterials. His professional experience spans academic research, diagnostic platform development, electrochemical biomarker detection, phospholipid self-assembly studies, and compliance testing of medical electrical equipment, reflecting both scientific depth and industry-relevant technical capability. Dr. Sut’s research focuses on lipid-based nanomaterials, membrane biophysics, antimicrobial lipids, diagnostic sensors, and therapeutic nanoplatforms, and he has authored numerous publications in high-impact journals that advance the understanding and application of functional biomimetic systems. His leadership includes serving as guest editor and topic editor for international journals, contributing to the curation of scholarly work in biomimicry, functional materials, and membrane science. He has been recognized through competitive research grants, academic scholarships, and editorial appointments that highlight his innovation, scientific rigor, and growing influence in the field. Through his combined research excellence, interdisciplinary training, and dedication to advancing diagnostic and therapeutic technologies, Dr. Sut demonstrates exceptional potential for continued contributions to scientific innovation and research leadership.

Profiles: Scopus | ORCID

Featured Publications

1. Molla, A., Sut, T. N., Yoon, B. K., & Jackman, J. A. (2025). Headgroup-driven binding selectivity of alkylphospholipids to anionic lipid bilayers. Colloids and Surfaces B: Biointerfaces.

2. Lee, C. J., Jannah, F., Sut, T. N., Haris, M., & Jackman, J. A. (2025). Curvature-sensing peptides for virus and extracellular vesicle applications. ACS Nano.

3. Kim, D., Baek, H., Lim, S. Y., Lee, M. S., Lyu, S., Lee, J., Sut, T. N., Gonçalves, M., Kang, J. Y., Jackman, J. A., & Kim, J. W. (2025). Mechanobiologically engineered mimicry of extracellular vesicles for improved systemic biodistribution and anti-inflammatory treatment efficacy in rheumatoid arthritis. Advanced Healthcare Materials.

4. Ruano, M., Sut, T. N., Tan, S. W., Mullen, A. B., Kelemen, D., Ferro, V. A., & Jackman, J. A. (2025). Solvent-free microfluidic fabrication of antimicrobial lipid nanoparticles. ACS Applied Bio Materials.

5. Hwang, Y., Zhao, Z. J., Shin, S., Sut, T. N., Jackman, J. A., Kim, T., Moon, Y., Ju, B. K., Jeoni, J. H., Cho, N. J., & Kim, M. (2025). Nanopot plasmonic sensor platform for broad spectrum virus detection. Chemical Engineering Journal.

Dr. Tun Naw Sut’s work advances next-generation diagnostic and therapeutic technologies through innovative biomimetic membrane engineering and lipid-based nanomaterials. His research contributes to global health by enabling more effective pathogen detection, improved targeted delivery systems, and transformative strategies for sensing and treating complex diseases.

Athanasios G. Mamalis | Materials Science | Academic and Industrial Collaboration Award

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Prof. Dr. Athanasios G. Mamalis | Materials Science | Academic and Industrial Collaboration Award

Scientific Director | Project Center for Nanotechnology and Advanced Engineering | Greece

Prof. Dr. Athanasios G. Mamalis is the Scientific Director of the Project Center for Nanotechnology and Advanced Engineering, a joint initiative of the Greek National Research Center “Demokritos” and the Russian Kurchatov Institute, and Emeritus Professor, Founder of the Laboratory of Manufacturing Technology at the National Technical University of Athens, Greece. A graduate in Mechanical and Electrical Engineering from the National Technical University of Athens, he earned his M.Sc. and Ph.D. in Mechanical Engineering from the Victoria University of Manchester Institute of Science and Technology. Dr. Mamalis has extensive industrial experience as Chief Engineer and Technical Manager in steelworks across Germany and Greece, complemented by long-standing collaborations with international industry including American, British, German, European, Japanese, Chinese, ex-Soviet, Hungarian, and Greek enterprises. He has held visiting professorships at Cambridge University, Universität Hannover, RWTH Aachen, and Carleton University, and full professorships at Michigan Technological University and the National Technical University of Athens. His research spans mechanics, manufacturing technology, precision and ultraprecision engineering, nanotechnology, ferrous and non-ferrous materials from macro- to nanoscale, powder production, biomechanics, vehicle structural safety, energy, environment, and industrial sustainability, resulting in over 32 books and monographs, 12 textbooks, 630 refereed journal and conference publications, and two patents. He has received numerous global recognitions, including election to several academies of sciences, multiple honorary professorships and doctorates, and fellowships and editorial roles in international scientific organizations and journals, reflecting his exceptional contributions to both theoretical and applied engineering and his enduring impact on global scientific and industrial advancement.

Profiles:  Scopus | ORCID

Featured Publications

1. Electroconsolidation method for fabrication of fine-dispersed high-density ceramics. Nanotechnology Perceptions, 2024.

2. Peculiarities of obtaining nanostructured materials compacted by the method of hot pressing due to the passage of direct electric current. Nanotechnology Perceptions, 2024.

3. Algorithmic foundations of optimization using finite element modeling of high-speed grinding technology in application to 3D micro-level models. Nanotechnology Perceptions, 2024.

4. Computer simulations of static stress-strain states for long-length pressurised pipes with external protective thin nanoengineered coating under nonuniform temperature fields. Nanotechnology Perceptions, 2024.

5. Magnetic shielding materials for electric vehicles. Nanotechnology Perceptions, 2024.

Lun Yang | Energy Materials | Best Researcher Award

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Dr. Lun Yang | Energy Materials | Best Researcher Award

Deputy Dean | Hubei Normal University | China

Dr. Yang Lun is an Associate Professor, Vice Dean, and Master’s Supervisor at the Institute of Scientific Research and Development, Hubei Normal University, and serves as Deputy Director of the Hubei Key Laboratory of Photoelectric Conversion Materials and Devices. He earned both his Bachelor’s and Doctoral degrees in Physics from Nanjing University, establishing a strong foundation in condensed matter physics, artificial intelligence, machine learning, and data science. Dr. Yang has demonstrated outstanding leadership in academia and administration, holding key positions in provincial and municipal committees, leading an Excellent Young and Middle-Aged Science and Technology Innovation Team, and serving as a technology advisor for small, medium, and micro enterprises in Hubei Province. Since joining Hubei Normal University, he has presided over numerous significant projects, including national and provincial research initiatives, industry-university collaborations, and teaching reform programs, while also contributing to high-impact research through over fifty SCI publications in international journals. His scholarly work spans semiconductor optoelectronic technology, condensed matter physics, and applied computational methods, with a strong record of mentoring students and developing professional curricula. Recognized for his academic and professional excellence, Dr. Yang has been appointed to several provincial science and technology leadership roles, participated in national research projects, and received multiple talent program selections for innovation and entrepreneurship. His contributions reflect a distinguished record of research leadership, educational impact, and professional service, positioning him as a leading figure in his field.

Profiles: Scopus 

Featured Publications

1. Enhanced thermoelectric properties in Cu12Sb4S13 tetrahedrite by incorporation of carbon-based nanoparticles. Vacuum, 2025.

2. Enhancing photoresponsivity of filterless narrowband photodetectors based on 2D perovskites by engineering a gradient bandgap. Optics and Laser Technology, 2025.

3. Precisely tailoring the d-band center of nickel sulfide for boosting overall water splitting. Applied Catalysis B: Environmental, 2024.

4. Five-level anti-counterfeiting based on versatile luminescence of tri-doped double perovskites. Nano Research, 2024.

5. Complementary multisite turnover catalysis toward superefficient bifunctional seawater splitting at ampere-level current density. Advanced Materials, 2024.

Liana Mogilnikova | Materials Science | Best Researcher Award

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Mrs. Liana Mogilnikova | Materials Science | Best Researcher Award

Liana Mogilnikova  | MISIS | Russia

Mrs. Liana Mogilnikova is a dedicated and accomplished researcher specializing in the study of hexagonal ferrites and magnetically hard materials. Her research focuses on understanding phase transformations and crystal structures, contributing valuable insights into the synthesis and characterization of strontium hexaferrite. Through meticulous experimentation and analytical precision, she has developed a comprehensive methodology for investigating the structural and phase states of ferrite materials. Her scholarly contributions, reflected in publications in reputed journals, demonstrate her commitment to advancing material science and magnetic materials research. With strong skills in data analysis, academic writing, and conference presentation, she effectively communicates complex scientific findings to the research community. Her work not only deepens the understanding of ferrite synthesis mechanisms but also lays the foundation for future innovations in nanostructured and energy-efficient magnetic materials, establishing her as a promising and impactful researcher in her field.

Profiles: Scopus | ORCID

Featured Publications

1. Mogilnikova, L. D., Menushenkov, V. P., Mogilnikov, P. S., & Savchenko, A. G. (2025). Phase transformations in the synthesis process of strontium hexaferrite SrFe₁₂O₁₉ by the sol-gel method. Journal of Alloys and Compounds, 1042, 183995.

Qian Qiao | Materials Science | Best Researcher Award 

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Dr. Qian Qiao | Materials Science | Best Researcher Award 

R&D Manager | IDQ Science and Technology (Hengqin Guangdong) Co | China

Dr. Qian Qiao is a dedicated researcher specializing in electromechanical and mechanical engineering, with extensive experience in materials science, surface technology, and smart manufacturing. She has authored numerous papers in reputable international journals and holds multiple patents that highlight her innovative approach to engineering challenges. Her academic achievements, including several prestigious scholarships and awards, reflect consistent excellence and commitment to research advancement. Dr. Qian has actively participated in global academic conferences, contributing to the dissemination and exchange of cutting-edge knowledge. Her current research focuses on the structural and performance analysis of advanced manufacturing components, integrating intelligent systems and automation to enhance efficiency and reliability. With a strong foundation in both theoretical and applied research, she demonstrates outstanding potential for leading future developments in material innovation, corrosion science, and intelligent engineering solutions, contributing meaningfully to technological progress and industrial transformation.

Profiles: Google Scholar | ScopusORCID 

Featured Publications

1. Qiao, Q., Qian, H., Li, Z., Guo, D., Kwok, C. T., Jiang, S., Zhang, D., & Tam, L. M. (2025). Microstructure evolution and mechanical performance of AA6061-7075 heterogeneous composite fabricated via additive friction stir deposition. Alloys, 4(4), 21.

2. Lam, W. I., Leong, K. K., Tam, C. W., Qiao, Q., Lin, Y., Yang, G., Guo, D., & Kwok, C. T. (2025). A high performance mechanically alloyed stainless steel composite coating via friction surfacing. Surface and Coatings Technology, 132685.

3. Qiao, Q., Gong, X., Guo, D., Qian, H., Li, Z., Zhang, D., Kwok, C., & Tam, L. M. (2025). Influence of tool head geometry on in situ monitoring of temperature, force, and torque during additive friction deposition of aluminum alloy 2219. Materials Science in Additive Manufacturing, 4(4), 025280060.

4. Qiao, Q., Tam, C. W., Lam, W. I., Wang, K., Guo, D., Kwok, C. T., Lin, Y., Yang, G., & Zhang, D. (2025). Hybrid heat-source solid-state additive manufacturing: A method to fabricate high performance AA6061 deposition. Journal of Materials Science & Technology, 228, 107–124.

5. Wu, Z., Qian, H., Chang, W., Zhu, Z., Lin, Y., Qiao, Q., Guo, D., Zhang, D., & Kwok, C. T. (2025). Enhanced corrosion resistance by Pseudomonas aeruginosa on 2219 aluminum alloy manufactured through additive friction stir deposition. Acta Metallurgica Sinica (English Letters), 1–18.

Vincelet Jobikha Arul Swamy | Materials Science | Women Researcher Award

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Ms. Vincelet Jobikha Arul Swamy | Materials Science | Women Researcher Award

Vincelet Jobikha Arul Swamy | Saveetha Engineering College | India

Ms. Vincelet Jobikha Arul Swamy is an emerging researcher in physics, pursuing her Ph.D. with a specialization in nanomaterials for energy production and advanced glass ceramics for radiation shielding. She has consistently demonstrated academic excellence with distinction in her undergraduate and postgraduate studies and has expanded her expertise through active participation in national and international conferences, workshops, and specialized training. Her innovative contributions include the development of a nanomaterial that enhances solar energy efficiency and the design of novel glass systems for radiation protection, supported by multiple granted patents. She has also presented her findings widely, published in reputed Scopus-indexed journals, and earned recognition for her impactful research. Alongside academics, she has built strong communication and leadership skills through co-curricular achievements. With a focus on interdisciplinary and application-oriented science, she is steadily building a profile of measurable research influence. Her Scopus record reflects 1 citation, 1 document, and an h-index of 1.

Profile: Scopus | ORCID

Featured Publications

1. P. Vinothkumar, B. Yamini, S. Praveenkumar, and A. Vincelet Jobikha, “Synthesis, structural, and optical properties of lead-free Tm3+ ions doped zinc tellurite glass and Ho3+ ions doped zinc borophosphate glass for radiation shielding application,” Radiation Physics and Chemistry, vol. 112955, 2025.

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Nikos Bikiaris | Materials Science | Distinguished Scientist Award

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Dr. Nikos Bikiaris | Materials Science | Distinguished Scientist Award

Postdoc researcher | Aristotle University of Thessalonik | Greece

Dr. Nikos Bikiaris is an accomplished researcher specializing in polymer chemistry, nanocomposites, and pharmaceutical technology, with a strong focus on the synthesis and characterization of bio-derived and biodegradable polymers, copolymers, and blends. His work bridges material science and pharmaceutical applications, particularly in the development of novel cosmeceutical formulations. He has gained significant expertise in advanced characterization techniques such as FTIR, NMR, XRD, DSC, TGA, GPC/SEC, and SEM, and his practical skills extend to polymer processing methods like spray drying and melt mixing. Dr. Bikiaris has contributed to numerous national and EU-funded projects, presenting his findings at international scientific conferences, and building a reputation as a collaborative and innovative researcher. His publications in high-impact journals reflect his commitment to advancing sustainable materials with real-world applications. His measurable research impact is demonstrated through Google Scholar metrics: Cited by All 1333, Since 2020 1326; h-index All 13, Since 2020 12; i10-index All 19, Since 2020 18.

Profile: Google Scholar

Featured Publications

1. E. Balla, V. Daniilidis, G. Karlioti, T. Kalamas, M. Stefanidou, N. D. Bikiaris, et al., “Poly (lactic Acid): A versatile biobased polymer for the future with multifunctional properties—From monomer synthesis, polymerization techniques and molecular weight increase,” Polymers, vol. 13, no. 11, p. 1822, 2021.

2. A. Vlachopoulos, G. Karlioti, E. Balla, V. Daniilidis, T. Kalamas, M. Stefanidou, et al., “Poly (lactic acid)-based microparticles for drug delivery applications: An overview of recent advances,” Pharmaceutics, vol. 14, no. 2, p. 359, 2022.

3. N. D. Bikiaris, I. Koumentakou, C. Samiotaki, D. Meimaroglou, D. Varytimidou, et al., “Recent advances in the investigation of poly (lactic acid)(PLA) nanocomposites: Incorporation of various nanofillers and their properties and applications,” Polymers, vol. 15, no. 5, p. 1196, 2023.

4. N. D. Bikiaris, G. Michailidou, M. Lazaridou, E. Christodoulou, E. Gounari, et al., “Innovative skin product emulsions with enhanced antioxidant, antimicrobial and UV protection properties containing nanoparticles of pure and modified chitosan with encapsulated …,” Polymers, vol. 12, no. 7, p. 1542, 2020.

5. N. D. Bikiaris, N. M. Ainali, E. Christodoulou, M. Kostoglou, T. Kehagias, et al., “Dissolution enhancement and controlled release of paclitaxel drug via a hybrid nanocarrier based on mpeg-pcl amphiphilic copolymer and fe-btc porous metal-organic framework,” Nanomaterials, vol. 10, no. 12, p. 2490, 2020.

Nazim Guseinov | Materials Science | Research and Development Achievement Award

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Mr. Nazim Guseinov | Materials Science | Research and Development Achievement Award

Researcher at Al-Farabi Kazakh National university, Kazakhstan

Mr. Nazim Guseinov is a dedicated researcher in nanotechnology with a strong academic background in solid-state physics and extensive professional experience at the National Nanotechnological Laboratory. His expertise lies in electron microscopy, electron spectroscopy, and electron/ion-beam lithography, which he applies to advanced material characterization and nanostructure fabrication. He has made significant contributions to research on carbon nanostructures, thin films, plasmonic nanocomposites, and graphene-based materials, combining both experimental and computational approaches. His work has been widely published in reputable international journals, reflecting consistent productivity and relevance to global scientific progress. Many of his studies address challenges in electronics, renewable energy, and advanced materials, showcasing the practical potential of his research. While his profile could be further strengthened by highlighting patents, leadership roles, and broader international collaborations, his achievements demonstrate a strong record of scientific excellence. Overall, Mr. Guseinov is a valuable contributor to nanoscience and a deserving candidate for recognition.

Professional Profile 

Scopus Profile | ORCID Profile 

Education

Mr. Nazim Guseinov has a strong educational foundation in physics, having completed both his bachelor’s and master’s degrees in solid-state physics at al-Farabi Kazakh National University. His studies provided him with a deep understanding of material properties, electronic structures, and physical phenomena at the atomic and nanoscale levels. This academic background laid the groundwork for his later specialization in nanotechnology, enabling him to combine theoretical knowledge with practical applications. His training emphasized advanced physics concepts, laboratory research, and modern characterization techniques, equipping him with the skills required to explore the behavior of materials at the nanoscale. The progression from undergraduate to postgraduate studies in the same field reflects a consistent dedication to mastering physics as a discipline. His educational journey has directly influenced his research focus, allowing him to bridge fundamental physics with applied nanoscience, and has positioned him well for a long-term career in advanced materials research.

Experience

Mr. Nazim Guseinov has extensive professional experience as a researcher at the National Nanotechnological Laboratory of Open Type in Kazakhstan, where he has been actively engaged since the beginning of his career. His primary responsibilities involve advanced experimental techniques such as electron microscopy and electron spectroscopy for material characterization, as well as electron-beam and ion-beam lithography for fabricating nanostructures. Over the years, he has contributed to the development and study of diverse nanomaterials, including carbon-based structures, thin films, and nanocomposites with potential applications in electronics and energy technologies. His professional role combines fundamental investigations with practical advancements, bridging academic research and applied innovation. By consistently engaging in multidisciplinary projects and co-authoring numerous scientific publications, he has established himself as a reliable and productive member of the scientific community. His long-term commitment to nanotechnology research demonstrates not only expertise in technical skills but also perseverance and dedication to advancing this field.

Research Focus

The core of Mr. Nazim Guseinov’s research lies in nanotechnology, with a particular emphasis on the study and fabrication of carbon nanostructures, thin films, and advanced nanocomposites. He specializes in applying high-resolution techniques such as electron microscopy and electron spectroscopy to investigate structural, electronic, and optical properties of materials at the nanoscale. His work extends to electron-beam and ion-beam lithography, enabling the creation of nanostructures with precision for scientific and industrial applications. He has also contributed to studies on plasmonic nanocomposites, graphene-based systems, and semiconductor materials, showcasing his versatility across multiple branches of nanoscience. His research outputs cover both experimental exploration and computational modeling, reflecting a comprehensive approach to material science. Many of his studies have potential applications in renewable energy, electronics, sensors, and data storage, demonstrating his focus on socially and technologically relevant areas. Overall, his research reflects a balance between advancing fundamental knowledge and exploring innovative practical solutions.

Award and Honor

While specific awards and honors are not listed in detail, Mr. Nazim Guseinov’s academic and research contributions are reflected through his extensive publication record in respected international journals. His involvement in collaborative projects with fellow scientists and contributions to multidisciplinary studies highlight his recognition within the scientific community. The consistent appearance of his work in high-impact publications such as Micromachines, Nanomaterials, and the Journal of Non-Crystalline Solids serves as an acknowledgment of the quality and significance of his research. Furthermore, his long-term role at a national nanotechnology research laboratory indicates institutional trust and recognition of his expertise in advanced materials research. Although additional details on individual awards, conference honors, or patents could further strengthen this section, his sustained academic productivity and contributions already reflect a form of professional distinction. Collectively, his achievements position him as a promising and deserving candidate for research recognition and professional honors.

Publication Top Notes

  • Electrostatic energy analyzer for nanotechnology applications
    Authors: Guseinov, N.R.; Ilyin, A.M.
    Year: 2021
    Citations: 10

  • Experimental investigation of the distribution of energy deposited by FIB in ion-beam lithography
    Authors: Muratov, M.; Myrzabekova, M.; Guseinov, N.; Nemkayeva, R.; Ismailov, D.; Shabelnikova, Y.; Zaitsev, S.
    Year: 2020

  • Organic Resist Contrast Determination in Ion Beam Lithography
    Authors: Shabelnikova, Y.L.; Zaitsev, S.I.; Guseinov, N.; Gabdullin, M.; Muratov, M.M.
    Year: 2020

  • Percolation conductivity in amorphous carbon films modified with palladium nanoparticles
    Authors: Ryaguzov, A.P.; Nemkayeva, R.R.; Guseinov, N.R.; Assembayeva, A.R.; Zaitsev, S.I.
    Year: 2020

  • Photoluminescence quenching of WS₂ nanoflakes upon Ga ion irradiation
    Authors: Bozheyev, F.; Nemkayeva, R.; Guseinov, N.; Kaikanov, M.; Tikhonov, A.
    Year: 2020

  • Computer simulation and first principles study of Ga-doped graphene nanostructures
    Authors: Ilyin, A.M.; Guseinov, N.R.; Kuanyshbekov, T.K.; Beall, G.W.; Tulegenova, M.A.
    Year: 2019

  • Computer simulation of the effect of structural defects on the effectiveness of graphene’s protective properties
    Authors: Tulegenova, M.; Ilyin, A.; Guseinov, N.; Beall, G.; Kuanyshbekov, T.
    Year: 2019

  • Influence of substrate temperature on the formation of titanium carbide film
    Authors: Kaipoldayev, O.E.; Baigarinova, G.A.; Nemkayeva, R.R.; Guseinov, N.R.; Mukhametkarimov, Y.S.; Tauasarov, K.; Prikhodko, O.Y.
    Year: 2019

  • Nanodefects on microcrystals of YAG-based phosphors
    Authors: Tulegenova, A.T.; Lisitsyn, V.M.; Abdullin, K.A.; Guseinov, N.R.
    Year: 2019

  • Study of the structure of amorphous carbon films modified with silicon oxide
    Authors: Ryaguzov, A.P.; Kudabayeva, M.A.; Nemkayeva, R.R.; Guseinov, N.R.; Myrzabekova, M.M.
    Year: 2019

Conclusion

Mr. Nazim Guseinov has built a strong research portfolio focused on nanotechnology, material science, and advanced electronic applications. His publications span high-impact areas such as electron-beam lithography, graphene-based nanostructures, amorphous carbon films, and photonic/electronic material properties. Collaborating with international teams, he has contributed to both experimental and computational studies that advance the understanding of nanostructured materials and their applications in electronics, sensing, and energy. While many of his works are relatively recent and still accumulating citations, the breadth of topics and consistent productivity highlight his role as an active and promising scientist. His research impact is evident through innovative approaches, interdisciplinary collaborations, and practical applications in nanotechnology, positioning him as a valuable contributor to modern materials science.