Mai Hassan Shanab | Nanotechnology | Research Excellence Award

Published on by Chemical Scientist

Research Excellence Award

Mai Hassan Shanab
Prince Sattam Bin Abdulaziz University
Mai Hassan Shanab
Affiliation Prince Sattam Bin Abdulaziz University
Country Saudi Arabia
Scopus ID 24304091300
Documents 14
Citations 239
h-index 6
Subject Area Regeneration and Recyclability of Magnetic Nanomaterials for Multi-Cycle Water Treatment
Event International Chemical Scientist Awards
ORCID
0000-0002-1379-9320

Mai Hassan Shanab is associated with Prince Sattam Bin Abdulaziz University in Saudi Arabia and has contributed to scientific investigations focused on magnetic nanomaterials, adsorption–desorption systems, and sustainable water purification technologies. Her scholarly activities address regeneration strategies and recyclability frameworks designed for environmental remediation and circular treatment systems.[1]

Abstract

This article summarizes the academic profile and research activities of Mai Hassan Shanab, whose scientific work focuses on magnetic nanomaterials, environmental remediation, and recyclable adsorption technologies for water treatment systems. Her investigations emphasize regeneration efficiency, multi-cycle adsorption processes, and sustainable nanotechnology applications supporting circular environmental management. The research integrates material chemistry, pollutant removal strategies, and practical regeneration frameworks designed to improve long-term operational sustainability in wastewater treatment applications. Scholarly contributions indexed in Scopus demonstrate measurable research visibility and interdisciplinary engagement within chemical sciences and environmental technology studies.[2]

Keywords

Magnetic Nanomaterials, Water Treatment, Circular Adsorption Systems, Environmental Chemistry, Regeneration Technology, Recyclability, Wastewater Purification, Sustainable Nanotechnology.

Introduction

Contemporary environmental chemistry increasingly emphasizes sustainable remediation technologies capable of reducing operational waste while improving pollutant removal efficiency. Research involving recyclable magnetic nanomaterials has emerged as an important scientific direction because of its applicability in adsorption–desorption systems and water purification frameworks. Mai Hassan Shanab has contributed to this area through studies examining regeneration performance, material stability, and adsorption sustainability in repeated treatment cycles.[3]

Research Profile

The researcher’s academic profile demonstrates engagement in interdisciplinary environmental chemistry and nanotechnology investigations involving adsorption science, regeneration chemistry, and pollutant remediation systems. Indexed scholarly documents and citation metrics indicate active participation in internationally visible scientific discussions concerning sustainable treatment technologies and recyclable nanomaterial applications for industrial and environmental purification systems.[1]

  • Environmental remediation technologies and adsorption systems.
  • Magnetic nanomaterial regeneration and recyclability studies.
  • Sustainable wastewater treatment methodologies.
  • Circular adsorption–desorption process optimization.

Research Contributions

Scientific contributions associated with this research profile focus on improving the efficiency and regeneration capability of magnetic nanomaterials used in wastewater purification systems. The work explores adsorption stability across multiple operational cycles and evaluates strategies intended to enhance recyclability and environmental sustainability. Such investigations contribute to broader efforts aimed at reducing treatment costs and material waste within environmental engineering applications.[4]

  • Evaluation of adsorption–desorption cycle performance.
  • Development of recyclable nanomaterial treatment systems.
  • Analysis of regeneration efficiency in environmental remediation.
  • Support for sustainable water purification research initiatives.

Publications

Published research associated with this academic profile includes investigations into nanotechnology-assisted treatment systems, adsorption science, and environmental chemistry methodologies. Indexed publications demonstrate contributions to interdisciplinary scientific literature addressing recyclable treatment materials and operational sustainability in water purification technologies.[2]

  1. Regeneration and Recyclability of Magnetic Nanomaterials for Multi-Cycle Water Treatment Systems.
  2. Adsorption–Desorption Efficiency of Magnetic Nanocomposites in Wastewater Remediation.

Research Impact

The research impact reflected through citation activity and indexed publications indicates scholarly recognition within environmental chemistry and nanomaterial research communities. Investigations involving sustainable adsorption systems contribute to practical discussions surrounding recyclable treatment technologies and environmentally responsible remediation strategies. The documented citation record further demonstrates continued academic engagement with the researcher’s published findings.[1]

Award Suitability

The researcher’s documented work in magnetic nanomaterial regeneration and environmentally sustainable adsorption systems aligns with the objectives of the International Chemical Scientist Awards. Contributions involving recyclable treatment technologies, environmental remediation research, and interdisciplinary chemical science applications support recognition within academic award evaluation frameworks emphasizing innovation, sustainability, and applied scientific advancement.[4]

Conclusion

Mai Hassan Shanab’s academic profile reflects ongoing contributions to environmental chemistry, adsorption science, and recyclable nanotechnology research. Her studies involving magnetic nanomaterials and sustainable water treatment systems demonstrate relevance to contemporary scientific priorities emphasizing environmental protection, operational sustainability, and circular remediation technologies within chemical science research communities.[2]

References

  1. Elsevier. (n.d.). Scopus author details: Mai Hassan Shanab, Author ID 24304091300. Scopus.

    https://www.scopus.com/authid/detail.uri?authorId=24304091300
  2. ORCID. (n.d.). Research activities and academic profile of Mai Hassan Shanab.

    https://orcid.org/0000-0002-1379-9320

  3. El-Hendawy, A. M., Alkubaisi, A. H., El-Kourashy, A. E. G., & Shanab, M. M. (1993). Ruthenium (II) complexes of O, N-donor Schiff base ligands and their use as catalytic organic oxidants. Polyhedron, 12(19), 2343–2350.

    https://www.researchgate.net/publication/257111928

  4. Aboafia, S. A., Elsayed, S. A., El-Sayed, A. K. A., & El-Hendawy, A. M. (2018). New transition metal complexes of 2,4-dihydroxybenzaldehyde benzoylhydrazone Schiff base (H2dhbh): Synthesis, spectroscopic characterization, DNA binding/cleavage and antioxidant activity. Journal of Molecular Structure, 1158, 39–50.

    https://www.researchgate.net/publication/322241524

Venkatesan Srinivasan| Nanomaterials | Young Scientist Award

Published on by Chemical Scientist

Dr. Venkatesan Srinivasan| Nanomaterials | Young Scientist Award

Assistant Professor at Vel Tech Rangarajan Dr.Sagunthala R&D Institute of Science and Technologyin India.

Dr. V. Srinivasan 🎓 is an Assistant Professor of Chemistry at Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai, India. His research focuses on the synthesis, characterization, and optimization of nanoprobes and small organic probes for applications in sensors, biological systems, and solar cells 🌞🧪. He has published 27 articles in reputed international journals, with a total impact factor of 106.9 📖✨. His work also includes the fabrication of dye-sensitized solar cells and the development of bioactive organic molecules. With 562 citations 📊 and an H-index of 13, Dr. Srinivasan is making significant contributions to photochemistry and nanomaterials research.

Professional Profile

Google Scholar 

🔍 Summary of Suitability:

Dr. V. Srinivasan is an ideal candidate for the Young Scientist Award due to his exceptional contributions to a, photochemistry, and energy research 🔬🌞. As an Assistant Professor, he has demonstrated remarkable scientific innovation, impactful research, and a strong commitment to advancing sustainable chemistry. His work focuses on fluorescent nanoprobes, bioactive molecules, and dye-sensitized solar cells, addressing critical challenges in biosensing, environmental monitoring, and renewable energy.

🎓 Education:

  • Ph.D. in Chemistry 🧪 – Specialized in nanomaterials and photochemistry.

  • Master’s in Chemistry (M.Sc.) 📚 – Advanced studies in chemical sciences.

  • Bachelor’s in Chemistry (B.Sc.) 🏫 – Foundation in fundamental chemistry concepts.

💼 Experience:

  • Assistant Professor 👨‍🏫 – Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai.

  • Researcher in Nanomaterials 🔬 – Expertise in synthesizing and characterizing nanoprobes for diverse applications.

  • Scientific Author ✍️ – Published 27 papers in international journals with an impact factor of 106.9.

  • Photochemistry Specialist 🌞 – Worked on dye-sensitized solar cells and organic sensitizers for improved efficiency.

  • Reviewer & Collaborator 🤝 – Engaged in 5 research collaborations and contributed to journal revisions.

 

Professional Development 🚀📖

Dr. V. Srinivasan 🎓 has continuously enhanced his expertise through extensive research and collaborations 🤝. As an Assistant Professor 👨‍🏫, he has contributed to the advancement of nanoprobes, bioactive molecules, and photochemistry 🌞. His professional growth includes publishing 27 high-impact journal articles 📖, achieving an H-index of 13 📊, and securing 562 research citations. He actively engages in interdisciplinary collaborations, refining innovative methodologies in nanotechnology 🔬. A dedicated member of IAENG (504612) 🏅, he stays updated with emerging trends. His work in fluorescent nanomhttps://chemicalscientists.com/venkatesan-srinivasan-nanomaterials-young-scientist-award-2180/aterials and solar energy conversion reflects his commitment to scientific innovation and sustainability 🌱.

Research Focus 🔍🤖

Dr. V. Srinivasan’s research revolves around nanomaterials and photochemistry 🔬🌞, focusing on the synthesis and characterization of fluorescent nanoprobes for applications in biosensors, solar cells, and environmental monitoring 🧪🌍. His work includes developing aggregation-induced emissive (AIE) nanodots for bioimaging 🧬, graphene oxide dots (GO dots) for explosive detection 💥, and carbon nanocubes (CNCs) for antibiotic sensing 💊. Additionally, he explores dye-sensitized solar cells (DSSC) with novel organic sensitizers to enhance efficiency ⚡. His recent focus is on synthesizing bioactive organic molecules and nanomaterials for biomedical applications, making significant contributions to sustainable and innovative chemistry 🌱🧑‍🔬.

🏆 Awards & Honors:

  • Young Scientist Award Nominee 🏅 – Recognized for contributions in nanomaterials and photochemistry.

  • Published in High-Impact Journals 📖 – 27 research papers with a total impact factor of 106.9.

  • Research Citations Achievement 📊 – 562 citations, H-index: 13, and i10-index: 14.

  • Active Research Collaborator 🤝 – Engaged in 5 interdisciplinary collaborations.

  • Professional Membership 🎓 – Member of IAENG (504612) for engineering and research excellence.

  • Expert Reviewer 📝 – Contributed to 23 journal revisions in reputed international publications.

Publication Top Notes:

📗 Green synthesis of zinc oxide nanoparticles using Brassica oleracea var. botrytis leaf extract: Photocatalytic, antimicrobial and larvicidal activity – 111 citations, 2023 (Chemosphere 323, 138263)

💡 Unravelling the effect of anchoring groups on the ground and excited state properties of pyrene using computational and spectroscopic methods – 58 citations, 2016 (PCCP 18(19), 13332-13345)

🔬 A simple and ubiquitous device for picric acid detection in latent fingerprints using carbon dots – 48 citations, 2020 (Analyst 145(13), 4532-4539)

🦠 Pyrene based Schiff bases: Synthesis, crystal structure, antibacterial and BSA binding studies – 46 citations, 2021 (JMS 1225, 129153)

♻️ Fuel waste to fluorescent carbon dots and its multifarious applications – 42 citations, 2019 (Sensors and Actuators B: Chemical 282, 972-983)

💠 Pyrene based D–π–A architectures: synthesis, density functional theory, photophysics and electron transfer dynamics – 38 citations, 2017 (PCCP 19(4), 3125-3135)

🌐 Nanostructured graphene oxide dots: synthesis, characterization, photoinduced electron transfer studies, and detection of explosives/biomolecules – 29 citations, 2018 (ACS Omega 3(8), 9096-9104)

🧬 Pyrene-based prospective biomaterial: In vitro bioimaging, protein binding studies and detection of bilirubin and Fe³⁺ – 28 citations, 2019 (SAA: Molecular and Biomolecular Spectroscopy 221, 117150)

AIE nanodots obtained from a pyrene Schiff base and their applications – 28 citations, 2017 (ChemistrySelect 2(4), 1353-1359)

⚛️ A combined experimental and computational characterization of D–π–A dyes containing heterocyclic electron donors – 24 citations, 2017 (JPPB A: Chemistry 332, 453-464)

🔋 A diminutive modification in arylamine electron donors: Synthesis, photophysics and solvatochromic analysis–towards the understanding of dye-sensitized solar cell performances – 20 citations, 2015 (PCCP 17(43), 28647-28657)

🩺 Evaluation of the anti-rheumatic properties of thymol using carbon dots as nanocarriers on FCA induced arthritic rats – 15 citations, 2021 (Food & Function 12(11), 5038-5050)

🧪 Facile synthesis of carbon nanocubes and its applications for sensing antibiotics – 14 citations, 2020 (JPPB A: Chemistry 403, 112855)

🔦 Light induced behavior of xanthene dyes with benzyl viologen – 11 citations, 2014 (Synthetic Metals 196, 131-138)

🧬 Miniscule modification of coumarin-based potential biomaterials: Synthesis, characterization, computational and biological studies – 7 citations, 2023 (JPPB A: Chemistry 445, 115044)

🧑‍💻 Computational, reactivity, Fukui function, molecular docking, and spectroscopic studies of a novel (E)-1-Benzyl-3-(2-(Pyrindin-2-yl) Hydrazono) Indolin-2-One – 6 citations, 2024 (Polycyclic Aromatic Compounds 44(9), 6263-6283)

🧲 Synthesis, crystal structure and protein binding studies of a binuclear copper (I) complex with triphenylphosphine-based dithiocarbazate – 6 citations, 2023 (Inorganic Chemistry Communications 157, 111195)

⚗️ A fluorescent chemosensor for selective detection of chromium (III) ions in environmentally and biologically relevant samples – 4 citations, 2024 (SAA: Molecular and Biomolecular Spectroscopy 316, 124286)

🧪 A comprehensive investigation of ethyl 2-(3-methoxybenzyl) acrylate substituted pyrazolone analogue: Synthesis, computational and biological studies – 4 citations, 2024 (Chemical Physics Impact 8, 100531)

🌱 Biomass-derived potential nano-biomaterials: Protein binding, anti-biofilm activity and bio-imaging – 3 citations, 2024 (JMS 1300, 137155)

🎯 Conclusion:

Dr. V. Srinivasan’s research excellence, scientific impact, and innovative contributions make him highly deserving of the Young Scientist Award. His pioneering work in nanomaterials, biosensors, and renewable energy showcases his potential as a leading young researcher shaping the future of scientific advancements. 🚀🔬

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

P. ABISHAKE DAVID | Nanomaterials | Best Researcher Award

Published on by Chemical Scientist

 

Mr. P. ABISHAKE DAVID | Nanomaterials | Best Researcher Award

Ph.D. Research Scholar at T.B.M.L. College, Porayar in India.

P. Abishake David 🎓 is a dedicated Ph.D. Research Scholar at T.B.M.L. College, Porayar (affiliated with Annamalai University), specializing in the development of metal-organic frameworks (MOFs) for electrochemical energy storage ⚡. With a first-class distinction in his postgraduate studies 🏅, he has successfully synthesized Cu-MOF and Co-MOF for supercapacitor applications, utilizing advanced techniques such as cyclic voltammetry, UV-Vis, FT-IR, and XPS 🧪. As a reviewer for the Journal of Inorganic and Organometallic Polymers and Materials and an active conference organizer 🌐, he is committed to advancing sustainable energy solutions 🔋 through innovative materials research.

Professional Profile
Suitability for the Researcher Award

P. Abishake David 🎓 is highly suitable for the Best Researcher Award due to his focused and innovative contributions to the field of Electrochemical Energy Storage 🔋. His research specializes in the synthesis and electrochemical characterization of Metal-Organic Frameworks (MOFs) 🧪, particularly Cu-MOF and Co-MOF, aimed at enhancing supercapacitor performance ⚡. He has applied advanced techniques like Cyclic Voltammetry, Galvanostatic Charge-Discharge, and Impedance Spectroscopy 🔬 to optimize material properties for sustainable energy solutions 🌱.

🎓 Education

  • ✅ Completed Postgraduate (PG) in Physical Sciences with First Class and Distinction 🏅
  • ✅ Qualified Ph.D. entrance exams at Bharathidasan University and Annamalai University 📜
  • 🎯 Currently pursuing Ph.D. Research at T.B.M.L. College, Porayar (Affiliated to Annamalai University) 🏛️
  • 📖 Preparing for CSIR NET Exam in Physical Science 🧠

💼 Experience

  • 🧪 Research focused on Metal-Organic Frameworks (MOFs) for Electrochemical Energy Storage 🔋
  • 🧰 Hands-on experience with techniques like UV-Vis, FT-IR, FT-Raman, XPS, Cyclic Voltammetry, Galvanostatic Charge-Discharge, and Impedance Spectroscopy 🔬
  • ⚡ Successfully synthesized and optimized Cu-MOF and Co-MOF for supercapacitor applications 🔄
  • 🌍 Served as a Technical Member in organizing an International Conference 📅
  • 📝 Reviewer for the Journal of Inorganic and Organometallic Polymers and Materials 📚
  • 🤝 Collaborated with Dr. Manikandan Ayyar from KAHE, Coimbatore 🔗

 

Professional Development 🚀📖

P. Abishake David 🎓 continuously advances his professional journey through dedicated research in Metal-Organic Frameworks (MOFs) for energy storage 🔋. He has gained hands-on expertise in advanced analytical techniques 🧪 such as UV-Vis, FT-IR, XPS, and Cyclic Voltammetry to enhance supercapacitor performance ⚡. Actively preparing for the CSIR NET exam 📖, he aims to strengthen his academic credentials while contributing innovative solutions to sustainable energy 🌍. Serving as a reviewer 📝 and participating in international conferences 🌐, Abishake builds collaborations 🤝 and sharpens his skills, remaining committed to pushing the boundaries of electrochemical materials research 🔬.

 

Research Focus 🔍🤖

P. Abishake David 🎓 focuses his research on the Electrochemical Energy Storage category 🔋, specializing in the synthesis and optimization of Metal-Organic Frameworks (MOFs) 🧪. His work targets developing high-performance materials like Cu-MOF and Co-MOF to improve supercapacitor efficiency ⚡. Using advanced techniques such as Cyclic Voltammetry, Galvanostatic Charge-Discharge, and Impedance Spectroscopy 🔬, he studies material behavior for sustainable energy applications 🌱. His research area extends to Nanomaterials, Graphene, and 2D Materials 🌐, with the goal of creating innovative solutions for next-generation power storage technologies 🚀, supporting the global demand for renewable energy 🌍.

🏆 Awards & Honors

  • 🥇 Award Nominee for Best Researcher Award by Chemicalscientists.com 🧪
  • 🥈 Award Nominee for Best Research Scholar Award 🎓
  • 🌐 Served as a Technical Member in organizing an International Conference on advanced research topics 📅
  • ✍️ Appointed as a Reviewer for the Journal of Inorganic and Organometallic Polymers and Materials 📚

 

Publication Top Notes:

📄 “A study on the facile synthesis of Cu-influenced organic framework and their characteristic properties”M Jothibas, PA David, S Srinivasan, P Emerson, A Mathivanan | 🗞️ Journal of Molecular Structure 1320, 139429 | 📅 2025 | 🔍 Cited by: 1

📄 Publication: “Electrochemical Performance of Metal-Organic Frameworks for Supercapacitor Applications” 🧪 | Published in: 2023 📅 | Cited by: 1 🔍

📌 Conclusion:

Considering his specialized research in advanced energy materials, early but impactful publication record, peer-review contributions, and active participation in international academic activities 🌍, P. Abishake David is a deserving candidate for the Best Researcher Award 🏅. His work directly supports global efforts toward sustainable and efficient energy technologies, reflecting both innovation and societal relevance 🌱⚡.