Ms. Alexandra Bargan, Institute of Macromolecular Chemistry Petru Poni Iassy, Romania
Dr. Alexandra Bargan is a distinguished Research Assistant at the Petru Poni Institute of Macromolecular Chemistry, Iasi, Romania. Her expertise lies in polymer and inorganic chemistry, focusing on advanced materials characterization and synthesis. She has co-authored 76 ISI articles, 38 of which are in Q1 journals, and has contributed to four book chapters, six conference proceedings, and two patent applications. As a project leader and member of numerous national and international grants, Dr. Bargan’s innovative research has garnered multiple awards, including gold and silver medals at INVENTICA. Her work on functionalized silica nanostructures and polysulfone membranes for CO₂ separation reflects her dedication to impactful research in chemistry and materials science.
Professional Profile:
Google Scholar
Suitability for the Best Researcher Awards: Dr. Alexandra Bargan
Summary of Suitability:
Dr. Alexandra Bargan is an accomplished researcher in polymer and inorganic chemistry, with an impressive academic and research portfolio that positions her as a strong candidate for a Best Researcher Award.
🎓Education
Dr. Bargan holds a robust academic foundation in chemistry. She earned her Ph.D. in polymer and inorganic chemistry, focusing on the synthesis and characterization of novel materials. Her postgraduate research provided her with advanced skills in techniques such as nuclear magnetic resonance, X-ray diffraction, and thermogravimetric analysis. Through continuous education, Dr. Bargan has mastered dynamic vapor sorption, surface tension analysis, and electron microscopy. Her academic achievements have laid the groundwork for her contributions to cutting-edge chemistry research, including functionalized silica nanostructures and silicone composites.
🏢Experience
Dr. Bargan has extensive experience in academic and applied research. As a Research Assistant at the Petru Poni Institute, she has been pivotal in numerous projects related to polymers and inorganic chemistry. Her leadership as Project Leader for the national grant “AI-Syn-PPOSS” showcases her skills in research design and innovation. Dr. Bargan has also contributed to the success of 20 national and international research grants. Her practical expertise includes developing silicone composites, synthesizing Schiff bases ligands, and designing advanced polysulfone membranes for CO₂ separation, making her a versatile and accomplished chemist.
🏅Awards and Honors
Dr. Bargan’s scientific excellence has earned her multiple accolades, including gold and silver medals at the prestigious INVENTICA conference. She has also received special recognition for her contributions to innovative chemistry research. As the Project Leader of the AI-Syn-PPOSS initiative, she was instrumental in developing advanced membranes with applications in gas separation, a project highly regarded in the research community. Her impactful publications, with a citation index of over 672 and an h-index of 17, further attest to her academic and professional achievements.
🔬Research Focus
Dr. Bargan’s research explores polymer and inorganic chemistry, emphasizing material characterization and synthesis. She specializes in the development of functionalized silica nanostructures, silicone composites, and Schiff base ligands derived from silicon compounds. Her groundbreaking work on polysulfone membranes impregnated with ionic liquids addresses critical challenges in CO₂ separation. Using advanced methods such as nuclear magnetic resonance, X-ray diffraction, and thermogravimetric analysis, Dr. Bargan combines innovative chemistry with practical applications to create materials with biomedical and environmental significance.
Publication Top Notes:
-
Study on cellulose nanofibrils/copolymacrolactone-based nano-composites with hydrophobic behavior, self-healing ability, and antioxidant activity
-
Dynamic Adsorption of a Cationic Dye onto Wool Fibers as Column-Filling Media: Response Surface Optimization and Fixed-Bed Adsorption Modeling
-
Experimental Studies of Surface Tensions for Binary and Ternary Systems of Benzyl Alcohol, N-Hexanol and Water. Modeling with Neural Networks
-
Synthesis and crystal structure of N1, N2-dimethylethanedihydrazide
-
Amino-functionalized silicones processed as porous dual covalent/supramolecular networks for pressure sensing
-
Hybrid green bionanocomposites based on chitosan/starch/gelatin and metallic nanoparticles for biological applications