Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award

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Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award

Prof. Dr. Shin’ya Obara , Thermochemistry , Factory of Engineering at Kitami Institute of Technology, Japan

Prof. Shin’ya Obara is a renowned academic in the field of energy systems, currently serving as Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido, Japan. He earned his B.S. and M.S. degrees in Mechanical Engineering from Nagaoka University of Technology in 1987 and 1989, respectively, and completed his Ph.D. in Mechanical Science at Hokkaido University in 2000. His career bridges academia and industry, including key roles in energy-focused companies and various educational institutes. Dr. Obara has dedicated his research to optimizing energy systems, advancing microgrid technologies, and enhancing the integration of renewable energy sources. He has authored or co-authored over 130 journal articles and is widely respected for his contributions to energy efficiency and sustainable systems. His diverse background brings a unique blend of theoretical insight and practical experience to the field of renewable energy and power systems engineering.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

rof. Shin’ya Obara is a distinguished researcher whose career focuses on energy systems optimization, including microgrids, renewable energy integration, and efficient operation of compound energy systems. His expertise lies primarily in mechanical and electrical engineering aspects of energy infrastructure, with strong emphasis on sustainability, reducing carbon emissions, and improving energy efficiency. While his work significantly contributes to green technologies and the broader goals of environmental sustainability, it is important to distinguish that Green Chemistry—as defined in scientific contexts—focuses specifically on designing chemical products and processes that reduce or eliminate the use and generation of hazardous substances. Green Chemistry deals with areas like greener synthesis pathways, safer solvents, bio-based feedstocks, waste minimization in chemical manufacturing, and environmentally benign chemical processes. Prof. Obara’s research aligns more directly with green energy engineering and sustainable energy systems rather than the core discipline of chemical process innovation or molecular-level chemistry transformations. His publications and projects involve energy networks, system modeling, and engineering solutions for renewable integration, rather than chemical synthesis or green chemical processes. Prof. Shin’ya Obara is an outstanding researcher in sustainable energy systems and green technology engineering, but he would not be a strong fit for a “Green Chemistry Award” focused strictly on chemistry. innovations.

🎓Education:

Prof. Shin’ya Obara pursued his academic journey in Japan, laying a solid foundation in mechanical and energy sciences. He received his Bachelor of Science in Mechanical Engineering from Nagaoka University of Technology in 1987. Continuing at the same institution, he completed his Master of Science in Mechanical Systems in 1989, delving deeper into the intricacies of machine design and thermal systems. While actively involved in industry and research, he furthered his education and earned a Ph.D. in Mechanical Science from Hokkaido University in 2000. His doctoral work focused on energy systems, contributing to the growing field of energy optimization. This unique trajectory—balancing rigorous academic study with practical research—helped shape his systems-based approach to power and energy engineering. His educational background provides a strong interdisciplinary platform for his ongoing research in renewable energy, microgrids, and system-level energy management.

🏢Work Experience:

Prof. Obara began his professional career with an eight-year tenure in industry, holding engineering and research positions at Takasago Thermal Engineering Co., Ltd. and Aisin AW Co., Ltd., where he gained hands-on experience in thermal systems and energy technologies. In 2000–2001, he served as a researcher in the Department of Mechanical Science at Hokkaido University. He transitioned to academia as an Associate Professor at Tomakomai National College of Technology in 2001 and became Professor of its Department of Mechanical Engineering in 2008. Since 2008, he has been Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido. Throughout his academic career, he has led numerous research projects and mentored students in areas related to energy systems and renewable integration. His combined industrial and academic experience strengthens his expertise in optimizing energy networks and deploying sustainable energy solutions.

🏅Awards: 

Prof. Shin’ya Obara has been recognized nationally and internationally for his contributions to energy systems and renewable technologies. Though specific awards are not listed in the given information, his authorship of over 130 peer-reviewed papers itself reflects a high level of academic and research excellence. He has likely received recognition through invitations to speak at international conferences, serve as a reviewer for prestigious journals, and lead funded projects in Japan. His role in shaping energy-efficient systems and microgrid optimization places him among influential researchers in sustainable engineering. Professors at his level in Japan often receive internal university awards, Japan Society for the Promotion of Science (JSPS) support, and government-funded grants. For a detailed list of specific honors and awards, his institutional CV or research profile would provide further insights. His enduring academic journey illustrates a career marked by consistent achievement and innovation.

🔬Research Focus:

Prof. Obara’s research centers on energy systems engineering, specifically involving the optimization of power and heat energy systems. He focuses on enhancing energy efficiency, integrating renewable energy sources, and developing microgrid technologies to support decentralized power generation. His work extends into energy network systems, where he explores the operation and simulation of compound energy systems, combining multiple energy sources for robust, resilient networks. He employs both theoretical modeling and experimental verification to refine the operational performance of hybrid energy systems. His contributions are highly relevant in addressing global sustainability challenges, particularly in designing green energy infrastructures that reduce carbon footprints. His research has practical implications for smart cities, off-grid communities, and industrial energy systems. Prof. Obara’s focus on interdisciplinary solutions—blending mechanical, electrical, and system sciences—makes his work highly impactful in the context of global energy transition.

Publication Top Notes:

1. Planning for local production and consumption of energy and electricity storage systems in regional cities, focusing on offshore wind power generation

2. Economic performance of combined solid oxide fuel cell system with carbon capture and storage with methanolation and methanation by green hydrogen

3. Capacity planning of storage batteries for remote island microgrids with physical energy storage with CO2 phase changes

Citations: 4

4. Comparative study of methods of supplying power to the lunar base

5. Development of energy storage device by CO2 hybridization of CO2 heat pump cycle and CO2 hydrate cycle

6. Fluctuation Mitigation Control of Wind Farm with Battery Energy Storage System and Wind Turbines’ Curtailment Function

7. Economic Analysis of SOFC Combined Cycle with CCS Accompanied by Methanation and Methanol Production

8. Equipment Sizing of a SOFC Triple Combined Cycle and a Hydrogen Fuel Generation System

9. Formation temperature range expansion and energy storage properties of CO2 hydrates

Citations: 4

Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

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Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

Dr. Faranak Hatami , Computational Chemistry , PhD at University of massachuessetes Lowell, United States

Faranak Hatami (Fara) is a dedicated physicist and researcher specializing in molecular dynamics simulations, machine learning, and nuclear materials science. Currently pursuing her Ph.D. in Physics at the University of Massachusetts Lowell, she focuses on transport property analysis and multi-objective optimization for molecular systems like Tri-Butyl-Phosphate (TBP). Faranak holds two master’s degrees—one in Physics from UMASS Lowell, where she explored force fields for TBP, and another in Nuclear Engineering from Shahid Beheshti University, where she investigated radiation damage in metals. With a robust background in computational physics, AI, and advanced simulation tools, she has authored multiple publications across nuclear materials and computational chemistry. Her teaching experience spans both the U.S. and Iran, reflecting her passion for education. Beyond academia, she completed a research internship at the University of Montreal. Faranak’s work bridges fundamental physics and practical applications, contributing innovative insights to the fields of material science and chemical engineering.

Professional Profile : 

Google Scholar 

Summary of Suitability for Award:

Faranak Hatami is a highly suitable candidate for a “Best Researcher Award”. She demonstrates exceptional multidisciplinary expertise spanning physics, molecular dynamics, machine learning, and nuclear materials science. Her Ph.D. work at UMASS Lowell innovatively combines atomic-scale simulations with AI to optimize force field parameters for Tri-Butyl-Phosphate, addressing both fundamental science and practical applications.  She has authored several impactful publications in reputable journals and preprints, covering diverse topics from radiation damage in metals to machine learning models predicting thermodynamic properties. Her research portfolio includes complex computational modeling, multi-objective optimization, and advanced materials analysis. Additionally, Faranak’s teaching record and successful research internship in Canada reflect her commitment to knowledge dissemination and international collaboration. Her ability to merge computational physics with machine learning showcases originality and forward-thinking, key attributes for top research honors. Faranak Hatami embodies the qualities of a best researcher: scientific rigor, innovative thinking, multidisciplinary skillset, and impactful publications. Her contributions significantly advance computational methods in physical sciences and engineering, making her a strong and deserving candidate for a “Best Researcher Award”.

🎓Education:

 Faranak Hatami is completing her Ph.D. in Physics at the University of Massachusetts Lowell (2021–2025), with her thesis focused on transport property analysis and optimization of force field parameters for Tri-Butyl-Phosphate (TBP), combining atomic-scale simulations with machine learning. Prior to this, she earned her M.Sc. in Physics from the same university in 2023, where she conducted a comparative study of force fields for liquid TBP using molecular dynamics. Earlier, she obtained her M.Sc. in Nuclear Engineering from Shahid Beheshti University in Iran (2016), where she examined radiation damage effects on zirconium and iron grain boundaries through simulations. Her academic journey began with a B.S. in Electrical Engineering from Kurdistan University in 2013. Throughout her studies, Faranak has integrated advanced computational methods, AI, and experimental data analysis, building a multidisciplinary foundation that connects physics, materials science, and engineering disciplines.

🏢Work Experience:

Faranak Hatami brings diverse experience across research, teaching, and technical projects. At UMASS Lowell, she serves as a Teaching Assistant in Physics while pursuing her Ph.D., guiding students through complex concepts. Previously, she lectured on Computational Methods and Statistical Methods and Physics courses at Shahid Beheshti University between 2014 and 2018. Her research career includes an internship at the University of Montreal (2019–2021), exploring hydrogen’s effects on iron grain boundaries using the kinetic activation relaxation technique (k-ART). Faranak has led significant academic projects spanning molecular dynamics simulations, multi-objective optimization, and machine learning applications in material science. She has deep expertise in computational tools such as LAMMPS, MCNP, VASP, and Python-based AI frameworks. Her work reflects a unique blend of fundamental physics research, practical problem-solving, and advanced data analysis, contributing to fields like chemical engineering, nuclear materials, and computational modeling.

🏅Awards: 

 Faranak Hatami has built an impressive research portfolio during her academic career, reflected in multiple publications and conference presentations. While specific named awards were not explicitly listed in her profile, her contributions have earned her recognition through invited presentations such as at the AIChE Annual Meeting, showcasing her expertise in molecular dynamics simulations and force field optimization. Completing dual M.Sc. degrees in Physics and Nuclear Engineering highlights her dedication and academic excellence. Her selection as a research intern at the University of Montreal, working on advanced computational studies in materials science, further underscores her capability and esteem in her field. Through her multidisciplinary approach integrating AI, molecular modeling, and nuclear materials science, she stands out as a rising scholar contributing valuable insights to computational physics and chemical engineering. As she advances her Ph.D., she is poised for further accolades in research innovation and scientific community engagement.

🔬Research Focus:

 Faranak Hatami focuses her research on the intersection of molecular dynamics simulations, machine learning, and materials science. Her Ph.D. work centers on analyzing transport properties and optimizing force field parameters for Tri-Butyl-Phosphate (TBP) using multi-objective optimization algorithms like NSGA-II/III. She applies molecular dynamics to predict critical thermodynamic and transport properties, integrating neural networks for parameter tuning. Additionally, she explores AI-based classification of microscopy and atomic-scale images, blending physics with cutting-edge data science. Faranak’s earlier research in nuclear engineering examined radiation damage in metals such as zirconium and nickel, utilizing techniques like climbing image nudged elastic band (CI-NEB) for defect analysis. She’s also investigated hydration free energies, grain boundary behaviors, and primary knock-on atom (PKA) spectra in irradiated materials. Her work bridges computational physics with practical engineering challenges, advancing predictive models and simulation methods to better understand complex molecular and material systems.

Publication Top Notes:

Comparative Analysis of Machine Learning Models for Predicting Viscosity in Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 6

Quantification of Methane Hydration Energy Through Free Energy Perturbation Method

Comparison of Different Machine Learning Approaches to Predict Viscosity of Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 3

Properties of Tri-Butyl-Phosphate from Polarizable Force Field MD Simulations

Citations: 1

A Revision of Classical Force Fields for Tri-N-Butyl Phosphate Molecular Dynamics Simulations

Interaction of primary cascades with different atomic grain boundaries in α-Zr: An atomic scale study

Citations: 34

An energetic and kinetic investigation of the role of different atomic grain boundaries in healing radiation damage in nickel

Citations: 31

Prof. Dr. Boguslaw BUSZEWSKI | Materials Chemistry | Analytical Chemistry Award

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Prof. Dr. Boguslaw BUSZEWSKI | Materials Chemistry | Analytical Chemistry Award

Prof. Dr. Boguslaw BUSZEWSKI ,  Materials Chemistry , Head at Prof. Jan Czochralski Kuyavien- Pomerania Research Development Center, Poland

Prof. Dr. Bogusław Buszewski is a distinguished Polish chemist renowned for his contributions to analytical chemistry and environmental chemistry. He graduated from Maria Curie-Skłodowska University in Lublin, Poland, and earned his Ph.D. in 1986, followed by a Dr Sc degree in 1992. In 1994, he was appointed as a full professor at Nicolaus Copernicus University in Toruń. His international experience includes a Humboldt Foundation scholarship at the University of Tübingen and a postdoctoral fellowship at Kent State University. Prof. Buszewski has served as a visiting professor at numerous universities across Europe, Asia, Australia, and America. He has authored over 750 scientific publications, holds numerous patents, and has supervised 50 doctoral and 25 habilitation theses. His work has garnered over 33,000 citations, reflecting his significant impact on the scientific community. He is a full member of the Polish Academy of Sciences and the European Academy of Sciences and Arts.

Professional Profile : 

Orcid

Summary of Suitability for Award:

Prof. Dr. Bogusław Buszewski stands as a global authority in the field of analytical chemistry, with extensive contributions spanning over four decades. His research has fundamentally advanced physicochemical separation techniques, including chromatography (HPLC, GC), electromigration techniques (CZE), spectroscopy (MALDI, ICP, MS), and environmental and bioanalytical applications.  Prof. Buszewski is a thought leader, having shaped analytical chemistry education and innovation across Europe and beyond. His methodologies are widely adopted in both academic and applied sciences for diagnostics, environmental monitoring, and material analysis. Prof. Dr. Bogusław Buszewski is highly suitable and an ideal candidate for the “Analytical Chemistry Award”. His pioneering research, extensive scholarly output, international collaborations, and transformative impact on separation science and bioanalytics make him a distinguished and deserving recipient of this prestigious recognition.

🎓Education:

Prof. Buszewski completed his chemistry studies at Maria Curie-Skłodowska University in Lublin in 1982. He earned his Ph.D. from the University in Bratislava in 1986 and obtained his DrSc degree in 1992. His academic journey was further enriched by international experiences, including a Humboldt Foundation scholarship at the University of Tübingen, Germany, and a postdoctoral fellowship at Kent State University, Ohio, USA. These experiences provided him with a broad perspective and deep expertise in analytical chemistry, laying the foundation for his future contributions to the field.

🏢Work Experience:

Prof. Buszewski’s illustrious career spans several decades, during which he has made significant contributions to analytical chemistry. Since 1994, he has been a full professor at Nicolaus Copernicus University in Toruń, where he also served as the head of the Department of Environmental Chemistry and Ecoanalytics. He has been instrumental in establishing a robust scientific school in Toruń, mentoring numerous students and researchers. His international engagements include visiting professorships at universities across Europe, Asia, Australia, and America. Prof. Buszewski has also held prominent positions such as the chairman of the Central European Group for Separation Sciences and the honorary chairman of the Committee of Analytical Chemistry of the Polish Academy of Sciences. His leadership roles have significantly influenced the direction of analytical chemistry research and education.

🏅Awards: 

Prof. Buszewski’s exceptional contributions to science have been recognized with numerous national and international awards. He has received multiple honorary doctorates from esteemed institutions, including the University of Bratislava, the University of Trnava, the Military Technical Academy, Wroclaw University of Environmental and Life Sciences, University of Warmia and Mazury, Poznan University of Technology, and Lodz University of Technology. His accolades include the Knight’s Cross and Officer’s Cross of the Order of Polonia Restituta, the Gold Cross of Merit, and medals from the National Education Commission, Societas Humboldtiana Polonorum, and the Kemuli and Heisenberg societies. These honors reflect his profound impact on the field of analytical chemistry and his dedication to scientific advancement.

🔬Research Focus:

Prof. Buszewski’s research encompasses a broad spectrum of analytical chemistry, with a particular emphasis on physicochemical separation techniques such as chromatography, electromigration methods, and spectroscopy. His work in developing advanced methods for sample preparation, environmental analysis, and bioanalysis has been pivotal in identifying biomarkers and understanding complex biological systems. He has also contributed significantly to the fields of nanotechnology and chemometrics. His interdisciplinary approach has led to innovations in the diagnosis of diseases through the analysis of exhaled air and the development of new materials for medical applications. Prof. Buszewski’s research not only advances scientific knowledge but also has practical implications in healthcare and environmental monitoring.

Publication Top Notes:

1. Potential Clinical Application of Analysis of Bisphenols in Pericardial Fluid from Patients with Coronary Artery Disease with the Use of Liquid Chromatography Combined with Fluorescence Detection and Triple Quadrupole Mass Spectrometry

2. In Vitro and In Silico of Cholinesterases Inhibition and In Vitro and In Vivo Anti-Melanoma Activity Investigations of Extracts Obtained from Selected Berberis Species

3. Development and Validation of LC-MS/MS Method for Determination of Cytisine in Human Serum and Saliva

4. Comprehensive Study of Si-Based Compounds in Selected Plants (Pisum sativum L., Medicago sativa L., Triticum aestivum L.)

5. Determination of Some Isoquinoline Alkaloids in Extracts Obtained from Selected Plants of the Ranunculaceae, Papaveraceae and Fumarioideae Families by Liquid Chromatography and In Vitro and In Vivo Investigations of Their Cytotoxic Activity

6. Exogenously Applied Cyclitols and Biosynthesized Silver Nanoparticles Affect the Soluble Carbohydrate Profiles of Wheat (Triticum aestivum L.) Seedling

7. Determination of Selected Isoquinoline Alkaloids from Chelidonium majus, Mahonia aquifolium and Sanguinaria canadensis Extracts by Liquid Chromatography and Their In Vitro and In Vivo Cytotoxic Activity against Human Cancer Cells

8. Functional Beverages in the 21st Century

9. The Association between the Bisphenols Residues in Amniotic Fluid and Fetal Abnormalities in Polish Pregnant Women—Its Potential Clinical Application

10. Analysis of VOCs in Urine Samples Directed towards Bladder Cancer Detection

11. Comparative Study of the Potentially Toxic Elements and Essential Microelements in Honey Depending on the Geographic Origin

12. Oligonucleotides Isolation and Separation—A Review on Adsorbent Selection

13. A New Approach to Imaging and Rapid Microbiome Identification for Prostate Cancer Patients Undergoing Radiotherapy

 

Assist. Prof. Dr. Ohyla El gammal | Inorganic Chemistry | Inorganic Chemistry Award

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Assist. Prof. Dr. Ohyla El gammal | Inorganic Chemistry | Inorganic Chemistry Award

Assist. Prof. Dr. Ohyla El gammal , Menofia university , Egypt

Dr. Ohyla Ahmed Abd El-Latif El-Gammal is an Egyptian inorganic chemist specializing in metal complexes, macrocyclic synthesis, and their biomedical applications. She earned her Ph.D. in Inorganic Chemistry from Menoufia University in 2014 and has extensive experience in academia, having served as a lecturer at Najran University, Saudi Arabia, and Menoufia University, Egypt. Her research explores spectroscopic characterization, γ-irradiation effects, and the biological activities of metal complexes. She has attended numerous international conferences and workshops, contributing to scientific discussions on materials science, analytical chemistry, and bioinorganic applications. Dr. Ohyla is actively involved in scientific publishing, having authored several high-impact journal articles. She is also dedicated to mentoring students and advancing knowledge in transition metal chemistry.

Professional Profile:

Scopus 

Summary of Suitability for Award:

Ohyla Ahmed Abd El-Latif El-Gammal is a highly suitable candidate for the “Inorganic Chemistry Award” due to her extensive contributions to the field of inorganic chemistry, particularly in the synthesis and characterization of metal complexes with biomedical applications. Her research focuses on developing innovative macrocyclic ligands, Schiff base complexes, and transition metal coordination compounds. She has made significant advancements in understanding the structural and functional properties of metal-based drugs, emphasizing their potential as anticancer, antimicrobial, and antioxidant agents.Ohyla El-Gammal is an excellent candidate for the “Inorganic Chemistry Award.” Her innovative work in metal complex synthesis, combined with her significant impact on medicinal and environmental chemistry, aligns perfectly with the award’s objectives. Her dedication to advancing inorganic chemistry through both theoretical and applied research makes her a deserving recipient of this prestigious recognition.

🎓Education:

Ohyla Ahmed Abd El-Latif El-Gammal obtained her B.Sc. in Chemistry from the Faculty of Science at Menoufia University, Egypt. She pursued postgraduate studies in Chemistry, further deepening her expertise in the field. She earned her M.Sc. in Inorganic Chemistry, focusing on the synthesis and characterization of metal complexes. Her academic journey culminated in a Ph.D. in Inorganic Chemistry, where she explored the design and application of macrocyclic metal complexes. Additionally, she obtained an ICDL certification, demonstrating her proficiency in information and communication technology. Throughout her education, she developed a strong foundation in coordination chemistry, spectroscopic techniques, and materials science, which later shaped her research interests in anticancer, antioxidant, and antimicrobial studies. Her educational background provided her with the necessary expertise to contribute significantly to the field of inorganic chemistry, particularly in the synthesis of innovative metal complexes with potential biomedical applications.

🏢Work Experience:

Ohyla El-Gammal has extensive experience in academia, serving as a Lecturer in Chemistry at various institutions. She has taught undergraduate courses in inorganic chemistry, transition metals, quantum chemistry, and analytical techniques. Her teaching career includes positions at Najran University, Saudi Arabia, where she contributed to the education of students in the fields of lanthanides, actinides, and phase chemistry. She also served as a faculty member at Northern Border University, Rafha, Saudi Arabia, specializing in principal group chemistry and spectroscopic methods. Additionally, she has been actively involved in laboratory-based instruction, focusing on qualitative and quantitative analytical chemistry. Apart from teaching, she has participated in numerous workshops and conferences, enhancing her expertise in scientific research and publishing. Her experience spans both theoretical and practical aspects of chemistry, making her a well-rounded academic professional with a strong commitment to research and education.

🏅Awards: 

Ohyla El-Gammal has received multiple accolades in recognition of her contributions to chemistry and academia. She has been honored for her participation in prestigious international scientific conferences and workshops, where she presented her research on metal complexes and their biomedical applications. She has actively engaged in high-impact research collaborations, earning recognition for her significant contributions to inorganic chemistry. She has also been acknowledged for her dedication to teaching and mentoring students, ensuring excellence in chemical education. Her involvement in major research projects and her participation in international scientific academies have further established her as a distinguished researcher. In addition, her research on macrocyclic complexes and their anticancer properties has been widely appreciated, leading to invitations to speak at global scientific forums. Her contributions to scientific publishing, along with her active role in international webinars, have cemented her reputation as a dedicated and accomplished chemist.

🔬Research Focus:

Ohyla El-Gammal’s research interests lie in inorganic chemistry, particularly in the synthesis and characterization of metal complexes with biomedical applications. She specializes in the development of macrocyclic ligands, transition metal coordination compounds, and Schiff base complexes. Her work explores the spectroscopic characterization of newly synthesized compounds, focusing on their structural and functional properties. She investigates the impact of γ-irradiation on metal complexes, studying their stability and enhanced biological activity. Her research extends to anticancer, antioxidant, and antimicrobial activities, aiming to develop novel therapeutic agents. She also works on improving the surface morphology of metal complexes for enhanced pharmaceutical applications. Her studies contribute significantly to the understanding of metal-based drugs and their potential in medicine. By integrating spectroscopic analysis and computational modeling, she continues to advance knowledge in the field of inorganic chemistry, contributing to the development of innovative materials for biomedical and environmental applications.

Publication Top Notes:

Synthesis, characterization, molecular docking and in vitro antibacterial assessments of anthracene-bis(hydrazine)thiosemicarbazide complexes with Co(II), Ni(II) and Cu(II) ions

Authors: O.A. El-Gammal, A.A. El-Bindary, A.M. Eldesoky, I.M. Abd Al-Gader

Journal: Journal of Molecular Structure

Year: 2025

Citations: 1

DNA binding, potential anticancer, antioxidant and molecular docking simulations of some isonicotinohydrazide metal complexes with the impact of high energy γ-rays irradiation doses: Synthesis and structural characterization

Authors: O.A. El-Gammal, H.A. El-Boraey, H. Alshater

Journal: Journal of Molecular Structure

Year: 2024

Citations: 1

Bishydrazone ligand and its Zn-complex: synthesis, characterization and estimation of scalability inhibition mitigation effectiveness for API 5L X70 carbon steel in 3.5% NaCl solutions

Authors: O.A. El-Gammal, D.A. Saad, M.N. El-Nahass, K. Shalabi, Y.M. Abdallah

Journal: RSC Advances

Year: 2024

Synthesis, structural characterization, antioxidant, cytotoxic activities and docking studies of schiff base Cu(II) complexes

Authors: G.N. Rezk, O.A. El-Gammal, S.H. Alrefaee, A.A. El-Bindary, M.A. El-Bindary

Journal: Heliyon

Year: 2023

Citations: 20

Synthesis, spectral, DFT, intrinsic constant of DNA binding and antioxidant activity of vanadyl (IV)2+^2+ complexes of a symmetrical bisthiosemicarbazides

Authors: O.A. El-Gammal, M.A.R. El-Nawawy, H.A. Gomaa, B.M. Ismael

Journal: Journal of Molecular Structure

Year: 2023

Citations: 4

Divalent transition metal complexes of multidentate nitrogen, oxygen and sulfur containing ligand: Design, spectroscopic, theoretical molecular modeling and antioxidant-like activity

Authors: B.M. Ismael, M.A.R. El-Nawawy, H.A. Gomaa, O.A. El-Gammal

Journal: Egyptian Journal of Chemistry

Year: 2022