Saida Mammadova | Surface Chemistry | Best Researcher Award Posted on 11/03/202511/03/2025 by chemical Scientist Dr. Saida Mammadova | Surface Chemistry | Best Researcher Award Scientific researcher at Institute of Physics, Azerbaijan. π¬ Saida Mammadova is a dedicated scientific researcher at the Institute of Physics, Ministry of Science and Education of Azerbaijan. With a Bachelorβs in Mathematics and a Masterβs in Mathematical Analysis from Baku State University, she later earned a PhD in Physics, specializing in topological effects in superconductors. Her research focuses on quantum computing, topological superconductivity, and lithium-ion batteries. She has published 8 journal papers, contributed to 4 research projects, and is actively involved in material simulations using QuantumATK. Her work is paving the way for next-gen quantum technologies. βοΈπ https://chemicalscientists.com/rudivan-eldik-bioinorganic-chemistry-lifetime-achievement-award-2107/ Professional Profile Google Scholar ScopusΒ Suitability for the Researcher Award Saida Mammadova is an exceptional researcher in the field of quantum physics and material science, with a strong academic background, extensive research contributions, and impactful innovations. Her expertise in topological superconductivity, quantum computing, and lithium-ion batteries has led to groundbreaking advancements in theoretical and applied physics. With over a decade of research experience, she has made significant strides in computational modeling, quantum materials, and spin-orbit interactions, making her a strong contender for the Best Researcher Award. Education π π Bachelorβs Degree in Mathematics β Baku State University π Masterβs Degree in Mathematical Analysis β Baku State University π PhD in Physics β Institute of Physics, Azerbaijan Specialized in Topological Effects in Superconductors with Spin-Orbit Interaction Experience π¬ π©βπ¬ Scientific Researcher β Institute of Physics, Ministry of Science and Education of Azerbaijan (10+ years) βοΈ Research Areas: Quantum Computing π₯οΈ Topological Superconductivity βοΈ Majorana Fermions π Density Functional Theory (DFT) π Lithium-Ion Batteries π Adsorption & Diffusion in Intermetallic Crystals ποΈ π₯οΈ Expert in Atomistic Simulations using QuantumATK π Published 8 research papers in indexed journals π Completed 4 research projects on quantum materials and superconductivity π€ Collaborated with Belarusian University on computational material simulations Professional Development ππ Saida Mammadova has continuously expanded her expertise in quantum physics and material science through advanced research and collaborations. π¬ She has contributed to four major research projects, focusing on quantum computing, topological superconductivity, and lithium-ion batteries. βοΈπ Her work with Belarusian University enhanced her skills in computational material simulations using QuantumATK. π₯οΈ She has published eight research papers in prestigious journals π and actively explores new theories in superconductivity and spin-orbit interactions. π Dedicated to innovation, she strives to bridge the gap between theoretical models and real-world quantum technologies. πβ¨ Research Focus ππ€ Saida Mammadova specializes in quantum physics and material science, focusing on topological superconductivity, quantum computing, and Majorana fermions. βοΈ She explores spin-orbit interactions and their effects on superconducting materials, contributing to next-generation quantum technologies. π₯οΈ Her research extends to Density Functional Theory (DFT), lithium-ion batteries, and adsorption/diffusion in intermetallic crystals, aiming to enhance energy storage and electronic applications. ππ She also utilizes advanced simulation tools like QuantumATK to develop innovative material models, shaping the future of superconductors and nanotechnology. ποΈπ Her work bridges theoretical insights with real-world applications in computational and experimental physics. π π Awards & Honors of Baiyan Li ποΈ World Federation of Scientists National Scholarship β Recognized for outstanding research in topological superconductivity in quasi-1D structures. π Women Research Award (Nominee) β Acknowledged for contributions to quantum computing and material science. π Published 8 research papers in prestigious SCI and Scopus-indexed journals. π¬ Completed 4 major research projects on quantum materials and superconductivity. π€ Collaborated with Belarusian University on advanced computational material simulations. Β Publication Top Notes: π Simulation of the adsorption and diffusion of lithium atoms on defective graphene for a Li-ion battery β MM Asadov, SO Mammadova, SS Huseynova, SN Mustafaeva, … | π Cited by: 6 | π Year: 2023 π Modeling of gold adsorption by the surface of defect graphene β MM Asadov, SO Mammadova, SS Guseinova, SN Mustafaeva, … | π Cited by: 6 | π Year: 2022 π Effect of the composition of a manganese-containing polymer catalyst on the kinetics of the oxidation reaction of n-heptane with molecular oxygen β AF Isazade, UA Mammadova, MM Asadov, NA Zeynalov, DB Tagiev, … | π Cited by: 5 | π Year: 2022 π Modeling structural and energy characteristics of atoms in a GaS2D-crystal with point defects β MM Asadov, SO Mammadova, SS Guseinova, SN Mustafaeva, … | π Cited by: 4 | π Year: 2022 π Ab initio calculation of the band structure and properties of modifications of the Ti3Sb compound doped with lithium β MM Asadov, SO Mammadova, SS Guseinova, SN Mustafaeva, … | π Cited by: 4 | π Year: 2022 π Modeling of the Electronic Properties of M-Doped Supercells Li4Ti5O12βM (Π = Zr, Nb) with a Monoclinic Structure for Lithium-Ion Batteries β MM Asadov, SO Mammadova, SN Mustafaeva, SS Huseynova, … | π Cited by: 2 | π Year: 2024 π Time-Reversal Invariant Topological Superconductivity in Quasi-One-Dimensional Structures β S Mammadova, E Nakhmedov, O Alekperov | π Cited by: 2 | π Year: 2016 π Adsorptive and colloidal-chemical characteristics of bentonite and its modified forms β AI Yagubov, NM Muradova, SA Mammadova, UH Osmanova, … | π Cited by: 2 | π Year: 2016 π Conclusion: Saida Mammadovaβs groundbreaking contributions, strong publication record, and dedication to advancing quantum materials research make her a highly deserving candidate for the Best Researcher Award. Her work bridges theoretical models with real-world applications, shaping the future of quantum computing, superconductivity, and nanotechnology. πβ¨
π¬ Saida Mammadova is a dedicated scientific researcher at the Institute of Physics, Ministry of Science and Education of Azerbaijan. With a Bachelorβs in Mathematics and a Masterβs in Mathematical Analysis from Baku State University, she later earned a PhD in Physics, specializing in topological effects in superconductors. Her research focuses on quantum computing, topological superconductivity, and lithium-ion batteries. She has published 8 journal papers, contributed to 4 research projects, and is actively involved in material simulations using QuantumATK. Her work is paving the way for next-gen quantum technologies. βοΈπ https://chemicalscientists.com/rudivan-eldik-bioinorganic-chemistry-lifetime-achievement-award-2107/ Professional Profile Google Scholar ScopusΒ
Saida Mammadova has continuously expanded her expertise in quantum physics and material science through advanced research and collaborations. π¬ She has contributed to four major research projects, focusing on quantum computing, topological superconductivity, and lithium-ion batteries. βοΈπ Her work with Belarusian University enhanced her skills in computational material simulations using QuantumATK. π₯οΈ She has published eight research papers in prestigious journals π and actively explores new theories in superconductivity and spin-orbit interactions. π Dedicated to innovation, she strives to bridge the gap between theoretical models and real-world quantum technologies. πβ¨ Research Focus ππ€ Saida Mammadova specializes in quantum physics and material science, focusing on topological superconductivity, quantum computing, and Majorana fermions. βοΈ She explores spin-orbit interactions and their effects on superconducting materials, contributing to next-generation quantum technologies. π₯οΈ Her research extends to Density Functional Theory (DFT), lithium-ion batteries, and adsorption/diffusion in intermetallic crystals, aiming to enhance energy storage and electronic applications. ππ She also utilizes advanced simulation tools like QuantumATK to develop innovative material models, shaping the future of superconductors and nanotechnology. ποΈπ Her work bridges theoretical insights with real-world applications in computational and experimental physics. π π Awards & Honors of Baiyan Li ποΈ World Federation of Scientists National Scholarship β Recognized for outstanding research in topological superconductivity in quasi-1D structures. π Women Research Award (Nominee) β Acknowledged for contributions to quantum computing and material science. π Published 8 research papers in prestigious SCI and Scopus-indexed journals. π¬ Completed 4 major research projects on quantum materials and superconductivity. π€ Collaborated with Belarusian University on advanced computational material simulations. Β
M. H. Keshavarz | Environmental Chemistry | Best Researcher Award Posted on 28/02/202528/02/2025 by chemical Scientist Prof. Dr. M. H. Keshavarz | Environmental Chemistry | Best Researcher Award Faculty of Applied Sciences, Malek Ashtar University of Technology, Iran π¬ Dr. Mohammad Hossein Keshavarz is a distinguished researcher in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). As a faculty member at Malek Ashtar University of Technology, Iran, he has made significant contributions to chemical safety, ecotoxicology, and sustainable chemistry. π He has authored several books and numerous high-impact journal articles, advancing predictive modeling and hazard assessment. His interdisciplinary work spans defense technology, materials science, and environmental protection. π Recognized for his leadership and innovation, Dr. Keshavarz continues to collaborate internationally, driving scientific advancements with practical applications. β¨ Professional Profile Google Scholar Scopus Orcid Suitability for the Researcher Award Dr. Mohammad Hossein Keshavarz is a highly accomplished researcher with significant contributions to environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). His interdisciplinary approach has led to advancements in chemical safety, hazard assessment, and sustainable chemistry. ππΏ EducationΒ π Ph.D. in Chemistry β Specialized in Environmental Toxicology & Energetic Materials M.Sc. in Chemistry β Focused on Quantitative Structure-Property Relationships (QSPR) B.Sc. in Chemistry β Strong foundation in chemical sciences and materials engineering Experience πΌ Professor, Faculty of Applied Sciences, Malek Ashtar University of Technology, Iran ποΈ Expert in Environmental Toxicology & Chemical Safety πΏβοΈ Extensive Research in Energetic Materials & Predictive Modeling (QSPR) π Published Multiple Books & High-Impact Journal Articles π Leader in Sustainable Chemistry & Hazard Assessment β οΈπ Collaborator with International Research Teams ππ€ Contributor to Defense & Industrial Applications of Chemistry ποΈπ‘ Professional Development ππ Dr. Mohammad Hossein Keshavarz has continually advanced his expertise through interdisciplinary research and global collaborations. ππ¬ He has authored numerous high-impact journal articles and books π, contributing significantly to environmental toxicology, chemical safety, and energetic materials. His work in predictive modeling (QSPR) enhances hazard assessment and sustainability. β οΈπΏ As a faculty member at Malek Ashtar University of Technology, he mentors young scientists while leading innovative research projects. ποΈπ¨βπ« Engaging in industrial and defense applications, he bridges academia and real-world chemical advancements. ποΈπ‘ His ongoing contributions solidify his role as a leader in analytical and applied chemistry. π Research Focus ππ€ Dr. Mohammad Hossein Keshavarz specializes in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). πΏβοΈ His research enhances chemical safety, ecotoxicology, and predictive modeling for hazardous substances. β οΈπ He explores green oxidizers, combustion properties, and stability of energetic compounds, contributing to sustainable chemistry and defense applications. π±π₯ His work also extends to materials science, polymer chemistry, and pharmaceutical toxicity assessments. ποΈπ With a focus on hazard mitigation and environmental sustainability, he applies computational and experimental methods to solve complex chemical challenges, bridging fundamental science with industrial and safety advancements. ππ Awards & Honors π Best Researcher Award β Recognized for outstanding contributions to analytical and environmental chemistry π π¬ Highly Cited Researcher β Extensive publications in high-impact journals with significant citations ππ International Collaborator Recognition β Honored for contributions to global scientific research partnerships ππ€ Excellence in Chemical Safety & Toxicology β Acknowledged for advancements in hazard assessment and sustainability β οΈπΏ Innovator in Energetic Materials β Awarded for breakthroughs in combustion properties and green oxidizers π₯β»οΈ Author of Distinguished Scientific Books β Recognized for influential publications in chemistry and material sciences πποΈ Publication Top Notes: π Nanoparticles of zinc sulfide doped with manganese, nickel and copper as nanophotocatalyst in the degradation of organic dyes β 461 π (2009)π An empirical method for predicting detonation pressure of CHNOFCl explosives β 124 π (2004)π Investigation of the various structure parameters for predicting impact sensitivity of energetic molecules via artificial neural network β 112 π (2006)π Simple empirical method for prediction of impact sensitivity of selected class of explosives β 103 π (2005)π Photocatalytic activity of mixture of ZrO2/SnO2, ZrO2/CeO2 and SnO2/CeO2 nanoparticles β 98 π (2012)π Magnetic properties and microwave absorption in NiβZn and MnβZn ferrite nanoparticles synthesized by low-temperature solid-state reaction β 97 π (2011)π Novel correlation for predicting impact sensitivity of nitroheterocyclic energetic molecules β 95 π (2007)π Theoretical prediction of electric spark sensitivity of nitroaromatic energetic compounds based on molecular structure β 82 π (2008) π Conclusion: Dr. Keshavarzβs exceptional research output, innovative methodologies, and real-world applications make him a highly deserving candidate for the Best Researcher Award. His contributions have positively impacted chemical safety, environmental science, and material sustainability, reinforcing his leadership in the scientific community. π
π¬ Dr. Mohammad Hossein Keshavarz is a distinguished researcher in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). As a faculty member at Malek Ashtar University of Technology, Iran, he has made significant contributions to chemical safety, ecotoxicology, and sustainable chemistry. π He has authored several books and numerous high-impact journal articles, advancing predictive modeling and hazard assessment. His interdisciplinary work spans defense technology, materials science, and environmental protection. π Recognized for his leadership and innovation, Dr. Keshavarz continues to collaborate internationally, driving scientific advancements with practical applications. β¨ Professional Profile Google Scholar Scopus Orcid Suitability for the Researcher Award
π¬ Dr. Mohammad Hossein Keshavarz is a distinguished researcher in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). As a faculty member at Malek Ashtar University of Technology, Iran, he has made significant contributions to chemical safety, ecotoxicology, and sustainable chemistry. π He has authored several books and numerous high-impact journal articles, advancing predictive modeling and hazard assessment. His interdisciplinary work spans defense technology, materials science, and environmental protection. π Recognized for his leadership and innovation, Dr. Keshavarz continues to collaborate internationally, driving scientific advancements with practical applications. β¨ Professional Profile Google Scholar Scopus Orcid
Ph.D. in Chemistry β Specialized in Environmental Toxicology & Energetic Materials M.Sc. in Chemistry β Focused on Quantitative Structure-Property Relationships (QSPR) B.Sc. in Chemistry β Strong foundation in chemical sciences and materials engineering Experience πΌ Professor, Faculty of Applied Sciences, Malek Ashtar University of Technology, Iran ποΈ Expert in Environmental Toxicology & Chemical Safety πΏβοΈ Extensive Research in Energetic Materials & Predictive Modeling (QSPR) π Published Multiple Books & High-Impact Journal Articles π Leader in Sustainable Chemistry & Hazard Assessment β οΈπ Collaborator with International Research Teams ππ€ Contributor to Defense & Industrial Applications of Chemistry ποΈπ‘
Dr. Mohammad Hossein Keshavarz has continually advanced his expertise through interdisciplinary research and global collaborations. ππ¬ He has authored numerous high-impact journal articles and books π, contributing significantly to environmental toxicology, chemical safety, and energetic materials. His work in predictive modeling (QSPR) enhances hazard assessment and sustainability. β οΈπΏ As a faculty member at Malek Ashtar University of Technology, he mentors young scientists while leading innovative research projects. ποΈπ¨βπ« Engaging in industrial and defense applications, he bridges academia and real-world chemical advancements. ποΈπ‘ His ongoing contributions solidify his role as a leader in analytical and applied chemistry. π Research Focus ππ€ Dr. Mohammad Hossein Keshavarz specializes in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). πΏβοΈ His research enhances chemical safety, ecotoxicology, and predictive modeling for hazardous substances. β οΈπ He explores green oxidizers, combustion properties, and stability of energetic compounds, contributing to sustainable chemistry and defense applications. π±π₯ His work also extends to materials science, polymer chemistry, and pharmaceutical toxicity assessments. ποΈπ With a focus on hazard mitigation and environmental sustainability, he applies computational and experimental methods to solve complex chemical challenges, bridging fundamental science with industrial and safety advancements. ππ Awards & Honors π Best Researcher Award β Recognized for outstanding contributions to analytical and environmental chemistry π π¬ Highly Cited Researcher β Extensive publications in high-impact journals with significant citations ππ International Collaborator Recognition β Honored for contributions to global scientific research partnerships ππ€ Excellence in Chemical Safety & Toxicology β Acknowledged for advancements in hazard assessment and sustainability β οΈπΏ Innovator in Energetic Materials β Awarded for breakthroughs in combustion properties and green oxidizers π₯β»οΈ Author of Distinguished Scientific Books β Recognized for influential publications in chemistry and material sciences πποΈ Publication Top Notes:
Dr. Mohammad Hossein Keshavarz has continually advanced his expertise through interdisciplinary research and global collaborations. ππ¬ He has authored numerous high-impact journal articles and books π, contributing significantly to environmental toxicology, chemical safety, and energetic materials. His work in predictive modeling (QSPR) enhances hazard assessment and sustainability. β οΈπΏ As a faculty member at Malek Ashtar University of Technology, he mentors young scientists while leading innovative research projects. ποΈπ¨βπ« Engaging in industrial and defense applications, he bridges academia and real-world chemical advancements. ποΈπ‘ His ongoing contributions solidify his role as a leader in analytical and applied chemistry. π Research Focus ππ€ Dr. Mohammad Hossein Keshavarz specializes in environmental toxicology, energetic materials, and quantitative structure-property relationships (QSPR). πΏβοΈ His research enhances chemical safety, ecotoxicology, and predictive modeling for hazardous substances. β οΈπ He explores green oxidizers, combustion properties, and stability of energetic compounds, contributing to sustainable chemistry and defense applications. π±π₯ His work also extends to materials science, polymer chemistry, and pharmaceutical toxicity assessments. ποΈπ With a focus on hazard mitigation and environmental sustainability, he applies computational and experimental methods to solve complex chemical challenges, bridging fundamental science with industrial and safety advancements. ππ Awards & Honors π Best Researcher Award β Recognized for outstanding contributions to analytical and environmental chemistry π π¬ Highly Cited Researcher β Extensive publications in high-impact journals with significant citations ππ International Collaborator Recognition β Honored for contributions to global scientific research partnerships ππ€ Excellence in Chemical Safety & Toxicology β Acknowledged for advancements in hazard assessment and sustainability β οΈπΏ Innovator in Energetic Materials β Awarded for breakthroughs in combustion properties and green oxidizers π₯β»οΈ Author of Distinguished Scientific Books β Recognized for influential publications in chemistry and material sciences πποΈ Publication Top Notes:
π Nanoparticles of zinc sulfide doped with manganese, nickel and copper as nanophotocatalyst in the degradation of organic dyes β 461 π (2009)π An empirical method for predicting detonation pressure of CHNOFCl explosives β 124 π (2004)π Investigation of the various structure parameters for predicting impact sensitivity of energetic molecules via artificial neural network β 112 π (2006)π Simple empirical method for prediction of impact sensitivity of selected class of explosives β 103 π (2005)π Photocatalytic activity of mixture of ZrO2/SnO2, ZrO2/CeO2 and SnO2/CeO2 nanoparticles β 98 π (2012)π Magnetic properties and microwave absorption in NiβZn and MnβZn ferrite nanoparticles synthesized by low-temperature solid-state reaction β 97 π (2011)π Novel correlation for predicting impact sensitivity of nitroheterocyclic energetic molecules β 95 π (2007)π Theoretical prediction of electric spark sensitivity of nitroaromatic energetic compounds based on molecular structure β 82 π (2008)
Dr. Keshavarzβs exceptional research output, innovative methodologies, and real-world applications make him a highly deserving candidate for the Best Researcher Award. His contributions have positively impacted chemical safety, environmental science, and material sustainability, reinforcing his leadership in the scientific community. π