Eman Helmy Ahmed Abdelmonaim | Pharmaceutical Sector Award | Women Researcher Award

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Dr. Eman Helmy Ahmed Abdelmonaim | Pharmaceutical Sector Award | Women Researcher Award

Dr. Eman Helmy Ahmed Abdelmonaim, National Research Centre NRC, Egypt

Eman Helmy Ahmed Abdelmonaim is an accomplished Egyptian researcher specializing in polymer science and nanotechnology. With a Ph.D. in Chemistry, she has conducted extensive research and received recognition for her work, including prestigious fellowships and awards. Her expertise spans various fields, from organic chemistry to spectroscopic techniques. Eman has contributed significantly to scientific conferences and publications, showcasing her innovative contributions to the field. With a passion for learning and a resilient attitude, she continues to excel in her endeavors, aiming to make impactful contributions to the scientific community. 🧪🔬

 

Publication Profile

Google Scholar

Education and Qualification 

Eman Helmy pursued her academic journey with dedication, starting from Al-Azhar Language School for her high school education in Nasr City, Egypt. She then obtained her Bachelor of Science degree in Special Chemistry from Al Azhar University, graduating with distinction in 2005. Her passion for organic chemistry led her to pursue further studies, culminating in a Master’s degree in Organic Chemistry from Cairo University in 2014. Her research focus on the preparation and characterization of polymeric nanocomposites earned her acclaim, with her thesis being examined by Prof. Dr. Patricia Heiden from Michigan Technological University, USA. In 2019, she successfully completed her Ph.D. in Chemistry, delving into the preparation of polymeric materials embedded in nano-structured oxides through joint supervision from Ain Shams University, Egypt, and Siegen University, Germany. 📚🎓

 

Research Focus

Eman Helmy Ahmed’s research focus revolves around the synthesis and characterization of advanced nanocomposites for various applications, particularly in dielectric materials and optical waveguide technologies. Her work encompasses the preparation and evaluation of hyperbranched polymers embedded with nanoparticles like montmorillonite clay and phosphosilicate, aiming at enhancing their dielectric and optical properties. Through her investigations, she explores the potential of these materials in fields such as electrical applications, planar optical waveguides, and friction coefficient modulation. Eman’s dedication to advancing nanotechnology contributes significantly to the development of innovative solutions for industrial and scientific challenges. 🔬✨

 

Publication Top Notes 

  1. Preparation and evaluation of hyperbranched p-chloromethyl styrene polymers/ montmorillonite clay nanocomposites as dielectric materials 📝 Cited by: 17, Year: 2015
  2. Phosphosilicate–polyamidoamine hyperbranched polymer–Er3+ nanocomposite toward planar optical waveguide applications 📝 Cited by: 13, Year: 2019
  3. Nanocomposites dendritic polyamidoamine-based chitosan hyperbranched polymer embedded in silica–phosphate for waveguide applications 📝 Cited by: 10, Year: 2021
  4. Influence of dispersing lithium grease by hybrid nano titanium and silicon oxides on friction coefficient 📝 Cited by: 10, Year: 2018
  5. Thermal Effect of Er³⁺ Ions Embedded in Smart Nano-Composite Oxide Material Prepared by Sol-Gel Technique 📝 Cited by: 10, Year: 2017
  6. Synthesis and cytotoxic activities of selenium nanoparticles incorporated nano-chitosan 📝 Cited by: 7, Year: 2024
  7. Influence of adding contaminants particles to lithium grease on the frictional coefficient 📝 Cited by: 6, Year: 2017
  8. Morphological and spectroscopical characterization of hyperbranched polyamidoamine–zwitterionic chitosan‑encapsulated 5‑FU anticancer drug 📝 Cited by: 5, Year: 2020
  9. Physical Properties of Tb3+ and Ho3+ Ions Embedded in Nanocomposites Phospho-Silicate📝 Cited by: 5, Year: 2020
  10. Dielectric behavior of some vinyl polymers/montmorillonite nanocomposites on the way to apply them as semiconducting materials 📝 Cited by: 5, Year: 2013