Nigora Qutlimurotova | Analytical Chemistry | Analytical Chemistry Award

Published on by Analytical Chemistry

Prof. Nigora Qutlimurotova | Analytical Chemistry | Analytical Chemistry Award

Professor | National university of Uzbekistan | Uzbekistan

Professor Qutlimurotova Nigora Khakimovna, D.Sc., is an accomplished analytical chemist and faculty member at the National University of Uzbekistan, renowned for her contributions to modern chemical analysis, particularly in the optical and electrochemical determination of heavy, toxic, and rare metal ions. With a solid academic foundation built at the National University of Uzbekistan, where she completed her B.Sc., M.Sc., and postgraduate studies in Analytical and Inorganic Chemistry, she progressed through academic roles from senior lecturer to professor, demonstrating consistent excellence in teaching, research, and scientific leadership. Her research focuses on developing innovative electrochemical and spectroscopic techniques for environmental monitoring, food quality control, and trace element analysis addressing pressing global needs for sensitive, fast, and reliable detection methods. Since earning her D.Sc. degree, Professor Qutlimurotova has produced over 100 scientific and methodological publications, including 28 papers in SAC-listed journals and 4 high-impact international journal articles, reflecting her scientific productivity and growing contribution to the field. Her notable recent works involve designing carbon quantum dots, novel organic ligands, and cyclic voltammetric systems for detecting biologically and environmentally significant ions such as vanadate, zirconium, cobalt, copper, and biomolecules like DNA and albumin. With an h-index of 2 (Web of Science & Scopus), she is steadily expanding her research visibility. Beyond research, she has enriched academic resources by authoring 8 educational handbooks, 3 methodological guides, and 1 monograph, and holds a patent for advanced scandium ion extraction technology, underscoring her innovative capabilities in separation chemistry. As a respected member of national scientific councils and chair of key academic committees, she actively contributes to advancing analytical chemistry education, mentoring young scholars, and promoting scientific excellence in Uzbekistan. Her broad engagement in scientific, social, and educational initiatives reflects her commitment to impactful research and community advancement.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

  • Agafonova, L. E., Bulko, T. V., Pronina, V. V., Qutlimurotova, N. H., & Shumyantseva, V. V. (2025). Carbon quantum dots in the electroanalysis of DNA and albumin. Bionanoscience, 15(3), 358.

  • Allambergenova, F., Smanova, Z., Qutlimurotova, N., Qutlimurotova, R., & Yakhshinorov, K. (2025). Synthesis of carbon dots based on chitosan and melamine and their application in detecting vanadate (V) anions. Chinese Journal of Analytical Chemistry, 53(7), Article 100538.

  • Kuronboyev, D., Faizullayeva, M., Kutlimurotova, N., Zulyarova, N., & Abdirahmonova, A. (2025). Development of a method for cyclic voltammetric determination of Copper(II) ions in the composition of technological objects. Chemical Review and Letters, 8(3), 469–481.

  • Karabayeva, G., Qutlimurotova, N., Yakhshieva, Z., Atakulova, N., & Tursunqulov, J. (2025). Development of a cyclic voltammetric method for the determination of Cobalt(II) ions using o-nitrosophenol. International Journal of Analytical Chemistry, 2025(1), Article 6675527.

  • Tursunqulov, J., Qutlimurotova, N., Fayzullayeva, M., Aliev, N., & Hosseini-Bandegharaei, A. (2025). Electrochemical determination of zirconium ions using 1-(2-hydroxy-1-naphthoyazo)-2-naphthol-4-sulphonic acid as a novel reagent. International Journal of Environmental Analytical Chemistry, 105(12), 2916–2939.

 

Shahryar Mooraj | Analytical Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Shahryar Mooraj | Analytical Chemistry | Best Researcher Award

Lawrence Livermore National Lab | United States

Dr. Shahryar Mooraj is a distinguished Post-Doctoral Researcher at Lawrence Livermore National Laboratory (LLNL), renowned for his groundbreaking contributions to metal additive manufacturing (AM) and advanced materials science. With a Ph.D. in Mechanical Engineering from the University of Massachusetts Amherst, his research spans the development of next-generation materials and fabrication processes that integrate precision engineering, artificial intelligence, and materials design. Dr. Mooraj’s scientific achievements are characterized by innovation in high-entropy alloys (HEAs), refractory materials, and hierarchical nanoporous structures. His research in microstructure control and defect mitigation has provided new insights into the mechanical and thermal behaviors of additively manufactured metals. His work on high-performance refractory alloys contributes to the design of plasma-facing materials for fusion energy systems, while his digital twin models enhance automation and defect prediction in manufacturing processes through AI integration. Notably, Dr. Mooraj developed a custom droplet-on-demand molten metal jetting system for boutique powder synthesis and created a rapid, cost-efficient platform for liquid metal wetting analysis, revolutionizing materials compatibility screening for AM. His investigations into hierarchical 3D architectures fabricated via direct ink writing (DIW) have also expanded the frontier of energy storage and electrocatalytic materials. His collaborations with leading global institutions including A*STAR (Singapore), Max Planck Institute (Germany), and ORNL (USA) underscore his role in advancing interdisciplinary materials research and fostering international scientific innovation. With 381 citations across 355 documents, 17 publications, and an h-index of 11 (Scopus), Dr. Mooraj’s scholarly impact reflects his sustained research excellence and leadership in additive manufacturing and material innovation. His forward-looking vision aims to establish sustainable, AI-driven, and defect-free manufacturing paradigms, aligning with global priorities in advanced materials design and next-generation engineering technologies.

Profiles : Scopus | ORCID | Google Scholar 

Featured Publications

Mooraj, S., Feng, S., Luebbe, M., Register, M., Liu, J., Li, T., Yavas, B., Schmidt, D. P., et al. (2025). Martensitic transformation induced strength-ductility synergy in additively manufactured maraging 250 steel by thermal history engineering. Journal of Materials Science & Technology, 211, 212–225.

Mooraj, S., Fu, J., Feng, S., Ng, A. K., Duoss, E. B., Baker, S. E., Zhu, C., Detsi, E., et al. (2024). Additive manufacturing of multiscale NiFeMn multi-principal element alloys with tailored composition. Materials Futures, 3(4), 045103.

Mooraj, S., Dong, X., Zhang, S., Zhang, Y., Ren, J., Guan, S., Li, C., Naorem, R., et al. (2024). Crack mitigation in additively manufactured AlCrFe₂Ni₂ high-entropy alloys through engineering phase transformation pathway. Communications Materials, 5(1), 101.

Mooraj, S., Kim, G., Fan, X., Samuha, S., Xie, Y., Li, T., Tiley, J. S., Chen, Y., Yu, D., et al. (2024). Additive manufacturing of defect-free TiZrNbTa refractory high-entropy alloy with enhanced elastic isotropy via in-situ alloying of elemental powders. Communications Materials, 5(1), 14.

Zhang, S., Hou, P., Kang, J., Li, T., Mooraj, S., Ren, Y., Chen, C. H., Hart, A. J., et al. (2023). Laser additive manufacturing for infrastructure repair: A case study of a deteriorated steel bridge beam. Journal of Materials Science & Technology, 154, 149–158.