Research Excellence Award

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]

External Links

• ORCID Profile
  
• Google Scholar Profile
• Scopus Author Profile
  
•  ResearchGate Profile
  
•  International Chemical Scientist Awards
  

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