Adnan Syed | Advanced Nanomaterials | Best Innovation Award

Published on by Global Nano Awards

Best Innovation Award

Adnan Syed
Cranfield University, United Kingdom
Adnan Syed
Affiliation Cranfield University
Country United Kingdom
Google Scholar ID bFPSfEAAAAJ&hl
Documents 22
Citations 404
h-index 8
Subject Area Advanced Nanomaterials
Event Global Nano Awards

The Best Innovation Award recognition article highlights the scholarly profile and research contributions of Adnan Syed, a researcher affiliated with Cranfield University in the United Kingdom. His published work spans advanced materials, corrosion science, energy systems, battery diagnostics, and nanotechnology-related applications. Through interdisciplinary investigations involving superheater corrosion, oxy-fuel combustion environments, ferritic alloy degradation, and lithium-ion battery health assessment, Syed has contributed to areas of engineering that support industrial sustainability and technological advancement. His research output demonstrates continued engagement with applied scientific challenges and reflects a commitment to evidence-based innovation in advanced materials and energy technologies.[1]

Abstract

Adnan Syed’s research portfolio encompasses advanced nanomaterials, corrosion engineering, power generation systems, and electrochemical energy storage. His scholarly work has addressed degradation mechanisms in high-temperature environments and developed analytical approaches for assessing material performance under industrial operating conditions. More recently, his investigations into machine-learning-assisted battery diagnostics demonstrate a transition toward intelligent monitoring systems and emerging energy technologies. Collectively, these contributions provide scientific insights relevant to reliability, efficiency, and sustainability across engineering sectors.[2]

Keywords

Advanced Nanomaterials, Corrosion Science, Oxy-Fuel Combustion, Superheater Materials, Ferritic Alloys, Energy Storage, Lithium-Ion Batteries, Machine Learning, Electrochemical Impedance Spectroscopy, Innovation Research.

Introduction

Innovation within engineering research frequently emerges from interdisciplinary studies that bridge materials science, energy systems, and computational analysis. Adnan Syed has contributed to this landscape through investigations focused on corrosion behavior in advanced power plants and diagnostic methodologies for modern battery technologies. His research activities have supported the understanding of operational reliability in demanding industrial environments while encouraging the development of more efficient technological solutions.[3]

Research Profile

With 22 indexed publications, 404 citations, and an h-index of 8, Syed has established a measurable academic presence in applied engineering research. His scholarly interests span corrosion degradation, advanced materials characterization, energy conversion technologies, and predictive health monitoring systems. The diversity of these topics illustrates a research trajectory that integrates experimental investigations with emerging analytical approaches.[1]

Research Contributions

  • Investigated fireside corrosion mechanisms in superheater components under coal and biomass combustion environments.
  • Evaluated degradation behavior of ferritic alloys under oxy-fired operating conditions.
  • Contributed to corrosion-resistant material assessment for advanced power generation facilities.
  • Applied machine learning and electrochemical impedance spectroscopy for lithium-ion battery health classification.
  • Supported research relevant to sustainability, reliability, and energy efficiency improvements.

Publications

  1. Fireside corrosion of superheaters: Effects of air and oxy-firing of coal and biomass (Fuel, 2012).
  2. Trends in fireside corrosion damage to superheaters in air and oxy-firing of coal/biomass (Fuel, 2013).
  3. Fireside corrosion of superheater materials in coal/biomass co-fired advanced power plants (Oxidation of Metals, 2013).
  4. Fireside corrosion degradation of ferritic alloys at 600°C in oxy-fired conditions (Corrosion Science, 2014).
  5. An SVM-based health classifier for offline Li-ion batteries by using EIS technology (Journal of The Electrochemical Society, 2023).

Research Impact

The citation performance of Syed’s publications indicates sustained academic interest in his findings. His highly cited studies on corrosion phenomena have informed discussions concerning materials durability in advanced power generation systems. Furthermore, his recent work involving support vector machine methodologies for battery assessment reflects the growing integration of artificial intelligence within engineering diagnostics. These contributions possess practical relevance for industrial operators, researchers, and technology developers.[4]

Award Suitability

Based on documented scholarly achievements, interdisciplinary research activities, and measurable citation impact, Adnan Syed demonstrates characteristics commonly associated with candidates for innovation-focused academic recognition. His work spans both established and emerging technological domains, connecting advanced materials research with intelligent diagnostic systems. Such a combination of foundational engineering knowledge and modern analytical techniques aligns with the objectives frequently emphasized by international research awards programs.[5]

Conclusion

Adnan Syed’s research record reflects a consistent contribution to engineering science through investigations in corrosion behavior, advanced materials, power generation systems, and battery diagnostics. His publications have contributed to understanding critical industrial challenges while supporting innovation in sustainable energy technologies. The breadth of his work and its measurable academic influence provide a strong foundation for recognition within international scientific and technological award platforms.

References

  1. Elsevier. (n.d.). Scopus author details: Adnan Syed, Author Profile. Scopus.
  2. Syed, A.U., Simms, N.J., & Oakey, J.E. (2012). Fireside corrosion of superheaters: Effects of air and oxy-firing of coal and biomass. Fuel.
    https://www.sciencedirect.com/science/article/abs/pii/S0016236111001384
  3. Hussain, T., Syed, A.U., & Simms, N.J. (2013). Trends in fireside corrosion damage to superheaters in air and oxy-firing of coal/biomass. Fuel
    .https://www.sciencedirect.com/science/article/pii/S0016236113002913
  4. Dudziak, T., Hussain, T., Simms, N.J., Syed, A.U., & Oakey, J.E. (2014). Fireside corrosion degradation of ferritic alloys at 600°C in oxy-fired conditions. Corrosion Science.
    https://link.springer.com/article/10.1007/s11085-013-9394-y
  5. Luo, W., Syed, A.U., Nicholls, J.R., & Gray, S. (2023). An SVM-based health classifier for offline Li-ion batteries by using EIS technology. Journal of The Electrochemical Society.
    https://iopscience.iop.org/article/10.1149/1945-7111/acc09f/meta
  6. Google Scholar. (n.d.). Adnan Syed Citation Profile.
    https://scholar.google.com/citations?user=_bFPSfEAAAAJ&hl=en

Habib Arabi | Advanced Nanomaterials | Research Excellence Award

Published on by Global Nano Awards

Research Excellence Award

Habib Arabi
Islamic Azad University
Habib Arabi
Affiliation Islamic Azad University
Country Iran
Scopus ID 57198192724
Documents 3
Citations 14
h-index 1
Subject Area Advanced Nanomaterials
Event Global Nano Awards
ORCID 0000-0001-6101-0710

Habib Arabi is an Iranian researcher affiliated with Islamic Azad University and associated with the University of Guilan in Rasht, Iran. His academic work primarily focuses on structural mechanics, functionally graded materials, vibration control systems, piezoelectric structures, and advanced computational mechanics. His scholarly contributions demonstrate interdisciplinary integration of mechanical engineering principles with intelligent computational frameworks and nanostructured material systems.[1]

The Research Excellence Award recognition highlights his contributions to analytical modeling, vibration suppression, thermo-fluidic structural analysis, and uncertainty-based mechanical optimization. His publications in internationally recognized journals demonstrate continued engagement with advanced engineering methodologies and material science applications.[2]

Abstract

This academic recognition article presents an overview of the research profile, scientific contributions, and scholarly achievements of Habib Arabi in the field of advanced mechanical systems and nanostructured engineering materials. His research emphasizes analytical and machine-learning-assisted modeling of functionally graded materials, vibration mitigation mechanisms, thermo-fluidic structural interactions, and piezoelectric control systems. The article further evaluates his contributions within the context of the Research Excellence Award associated with the Global Nano Awards initiative.[3]

Keywords

Advanced Nanomaterials, Functionally Graded Materials, Piezoelectric Structures, Structural Dynamics, Vibration Control, Thermo-Fluidic Systems, Mechanical Engineering, Computational Mechanics, Auxetic Graphene Origami, Research Excellence Award

Introduction

Contemporary engineering research increasingly integrates computational intelligence, multifunctional materials, and nanoscale structural optimization to improve mechanical performance and dynamic stability. Researchers working within this domain contribute to the development of lightweight structures, adaptive materials, and advanced vibration suppression technologies suitable for aerospace, civil, and industrial engineering systems.[4]

Habib Arabi has contributed to this evolving scientific landscape through investigations into functionally graded plates, porous sandwich microstructures, piezoelectric control systems, and uncertainty-aware mechanical modeling. His publications indicate an emphasis on theoretical mechanics supported by analytical and computational methodologies, particularly in relation to dynamic stability and vibration mitigation.[5]

Research Profile

Habib Arabi maintains academic associations with Islamic Azad University of Garmsar and the University of Guilan in Iran. His Scopus author profile records scholarly activity in mechanical engineering and computational structural analysis with publications addressing vibration control, porous sandwich systems, and finite mechanical modeling.[1]

The researcher’s academic trajectory demonstrates sustained interest in smart materials and adaptive structural systems. His work integrates functionally graded materials with piezoelectric layers to improve dynamic performance under uncertain environmental and mechanical conditions. Several studies also investigate nonlinear system behavior, thermal interactions, and machine-learning-assisted predictive modeling frameworks.[6]

Research Contributions

One of the major research themes explored by Habib Arabi involves vibration suppression in functionally graded material systems using piezoelectric control strategies. These studies address uncertainty conditions and dynamic disturbances through advanced computational methodologies such as Markovian jump models and robust control systems.[7]

Another important contribution relates to thermo-fluidic analysis of porous sandwich microplates incorporating auxetic graphene origami cores. This research integrates analytical mechanics with machine learning approaches to predict and optimize vibration characteristics within multifunctional engineering structures.[8]

His earlier work additionally examined elastic stress fields near bimaterial notches, contributing to understanding fracture mechanics and structural durability in composite systems. These investigations provide theoretical insights into stress singularities and material interface behavior.[9]

  • Analytical modeling of functionally graded porous structures
  • Machine-learning-assisted vibration prediction frameworks
  • Piezoelectric-based vibration control systems
  • Stress field analysis in composite and bimaterial systems
  • Thermo-fluidic interaction modeling for advanced materials

Publications

  1. Analytical-machine learning framework for free vibration of functionally graded porous sandwich microplates with auxetic graphene origami cores in a thermo-fluidic environment, Mechanics Based Design of Structures and Machines, 2026.
  2. Robust active vibration control of FGMs plate with uncertainties and jump in mechanical properties under disturbed conditions using piezoelectric layers, International Journal of Structural Stability and Dynamics, 2025.
  3. Response Suppression of FGM Plate Using Piezoelectric Layers Under Parametric Uncertainty Conditions with Markovian Jump Approach, International Journal of Computational Methods, 2021.
  4. Study of Characteristic Equation of the Elastic Stress Field Near Bimaterial Notches, Strength of Materials, 2013.

Research Impact

The research impact associated with Habib Arabi’s scholarly profile includes contributions to structural optimization methodologies and vibration control technologies applicable to advanced engineering systems. His studies on functionally graded materials and piezoelectric structures support ongoing developments in lightweight multifunctional engineering designs and smart adaptive materials.[10]

His Scopus-indexed publications and citation record indicate emerging recognition within computational mechanics and structural dynamics communities. The interdisciplinary combination of machine learning, mechanics, and nanostructured material analysis reflects alignment with contemporary engineering research priorities.[1]

Award Suitability

The Research Excellence Award acknowledges researchers demonstrating measurable scholarly engagement, innovation in specialized scientific domains, and contributions to advanced technological methodologies. Habib Arabi’s investigations into adaptive material systems, computational mechanics, and intelligent vibration control demonstrate relevance to emerging scientific and industrial challenges within advanced nanomaterials and engineering structures.[11]

His work reflects integration of analytical theory with modern computational frameworks, particularly in the context of uncertainty-aware structural systems and smart material applications. Such contributions align with the broader objectives of the Global Nano Awards in recognizing interdisciplinary innovation and engineering advancement.[12]

Conclusion

Habib Arabi’s academic profile represents a developing body of research focused on advanced mechanical systems, smart material integration, vibration control, and computational engineering analysis. Through publications addressing functionally graded materials, piezoelectric structures, and thermo-fluidic interactions, he contributes to contemporary research in structural mechanics and advanced engineering materials.[13]

The Research Excellence Award recognition within the framework of the Global Nano Awards highlights the significance of interdisciplinary engineering research and the growing importance of intelligent computational methodologies in modern material science and mechanical engineering applications.[14]

References

  1. Elsevier. (n.d.). Scopus author details: Habib Arabi, Author ID 57198192724. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57198192724
  2. Global Nano Awards. (2026). Research Excellence Award recognition framework.
    https://globalnanoawards.com/
  3. Arabi, H. (2026). Analytical-machine learning framework for free vibration of functionally graded porous sandwich microplates with auxetic graphene origami cores in a thermo-fluidic environment.
    https://doi.org/10.1080/15397734.2026.2630058
  4. International engineering literature discussing multifunctional material systems and smart adaptive structures.
  5. Arabi, H. (2025). Robust active vibration control of FGMs plate with uncertainties and jump in mechanical properties under disturbed conditions using piezoelectric layers.
    https://doi.org/10.1142/S0219455427501835
  6. ORCID. (n.d.). Habib Arabi researcher profile and scholarly works.
    https://orcid.org/0000-0001-6101-0710
  7. Arabi, H. (2021). Response Suppression of FGM Plate Using Piezoelectric Layers Under Parametric Uncertainty Conditions with Markovian Jump Approach.
    https://doi.org/10.1142/S0219876221500493
  8. Mechanics Based Design of Structures and Machines. (2026). Advanced analytical-machine learning frameworks for porous sandwich microplates.
  9. Arabi, H. (2013). Study of Characteristic Equation of the Elastic Stress Field Near Bimaterial Notches.
    https://doi.org/10.1007/s11223-013-9497-3
  10. Research literature in structural dynamics and smart material engineering applications.
  11. Global Nano Awards. (2026). Recognition criteria for interdisciplinary engineering innovation.
  12. Academic literature concerning intelligent computational methodologies in engineering sciences.
  13. University and author profile records documenting Habib Arabi’s scholarly activities and publication history.
  14. Global Nano Awards. (2026). Research Excellence Award documentation and academic recognition initiatives.
    https://globalnanoawards.com/

Ce Wang | Advanced Nanomaterials | Lifetime Achievement Award

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Prof. Ce Wang | Advanced Nanomaterials | Lifetime Achievement Award

Jilin University | China

Prof. Ce Wang is a highly influential materials scientist with a distinguished research record in nanofibers, polymer science, electrospinning, and advanced fiber-based composite materials. Her scholarly output includes 506 Scopus-indexed documents with 24,723 citations and an h-index of 80, reflecting sustained global impact and high research visibility. Her work spans fundamental research, applied R&D, and translational innovation in functional nanomaterials, ultrafine fiber composites, smart textiles, and high-performance polymer systems. She has contributed extensively to high–impact international journals, served as an active reviewer and editorial contributor, and played key roles in shaping conference programs and scientific discourse in nanotechnology and materials science. Prof. Ce Wang has led and participated in numerous competitive research and funding projects, generated impactful research findings, and advanced technology transfer through patents and industrially relevant innovations. Her research excellence has been recognized through multiple prestigious awards and honors, underscoring her significant contributions to scientific advancement, innovation, and the global nanotechnology research community.

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Parmeshwar Lal Meena | Advanced Nanomaterials | Best Academic Researcher Award

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Assist. Prof. Dr. Parmeshwar Lal Meena | Advanced Nanomaterials | Best Academic Researcher Award

Assistant Professor | University of Rajasthan | India

Assist. Prof. Dr. Parmeshwar Lal Meena is an accomplished researcher in chemistry with a strong focus on water remediation, hydrogeochemistry, photocatalysis, nanomaterials, and polymer-based nanocomposites for environmental applications. His scholarly output includes 74 research documents indexed on Google Scholar, accumulating 981 citations, with an h-index of 17 and an i10-index of 27, reflecting sustained research impact and quality. His work spans high-impact journal articles, authoritative review papers, edited book chapters, and conference publications, contributing significant advances in green nanomaterial synthesis, groundwater quality assessment, and pollutant removal technologies, and earning recognition within the scientific research community.

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Ali Raza Kashif | Advanced Nanomaterials | Young Researcher Award

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Mr. Ali Raza Kashif | Advanced Nanomaterials | Young Researcher Award

Research Assistant | Huazhong University of Science and Technology | China

Mr. Ali Raza Kashif is an emerging researcher in materials science and nanotechnology with a focused record of peer-reviewed research addressing sustainable nanomaterials, green synthesis, and multifunctional nanocomposites. His scholarly contributions include journal publications exploring plant-mediated synthesis of metal and metal-oxide nanoparticles, photocatalytic degradation of environmental pollutants, and bioactive nanomaterials with antioxidant, antimicrobial, and biomedical relevance. His research portfolio also spans adsorptive nanocomposites for water remediation and nanostructured materials for energy-related applications, reflecting strong interdisciplinary integration of chemistry, materials science, and nanobiotechnology. With Scopus-indexed outputs totaling 4 documents, 13 citations, and an h-index of 2, his work demonstrates growing academic visibility and impact. He has contributed to collaborative research projects, participated in international scientific conferences, and supported peer review activities, highlighting engagement with the global research community. Overall, his research profile reflects innovation-driven contributions to sustainable nanomaterials, environmental remediation, and applied nanoscience.

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Yuanwei Lu | Advanced Nanomaterials | Research Excellence Award

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Dr. Yuanwei Lu | Advanced Nanomaterials | Research Excellence Award

Doctor | Harbin Institute of Technology | China

Dr. Yuanwei Lu is a researcher specializing in nanomaterials for energy-efficient and smart optical applications, with a focused body of work spanning photochromic and thermochromic materials, smart windows, and radiative cooling technologies. His research integrates nanoscale materials design, optical–thermal regulation, and functional performance evaluation to control solar and thermal radiation for sustainable energy systems. He has authored peer-reviewed journal articles indexed in Scopus, contributing to high-impact outlets in materials chemistry and energy science, with a current record of 7 documents, 16 citations, and an h-index of 3. His research contributions include the development of thermo-erasable photochromic nanocomposites with enhanced cycling stability, environmental durability, and scalable fabrication potential, advancing rewritable optical media and smart surface technologies. Dr. Yuanwei Lu’s work demonstrates clear innovation at the intersection of nanomaterials engineering and energy applications, supporting progress in sustainable building technologies, advanced functional materials, and applied research with translational potential.

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Y. Christabel Shaji | Advanced Nanomaterials | Best Researcher Award

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Dr. Y. Christabel Shaji | Advanced Nanomaterials | Best Researcher Award

Assistant Professor | Holy Cross College (Autonomous) | India

Dr. Y. Christabel Shaji is an active researcher in chemistry with significant contributions spanning polymer chemistry, nanomaterials, metal–organic frameworks, and functional inorganic materials. Her research emphasizes the synthesis, characterization, and application of advanced materials, including poly(ester-imide)s, Schiff base metal complexes, green-synthesized nanoparticles, and MOF-based systems for photocatalysis, antimicrobial activity, and targeted cancer drug delivery. She has authored peer-reviewed journal articles and conference publications, including works indexed in Scopus and Web of Science, and has contributed to scholarly books and book chapters in chemical and materials sciences. Her innovation portfolio includes granted and published patents in nanogels, composite materials, and drug-delivery technologies. Dr. Y. Christabel Shaji has led and participated in funded research projects, supervised interdisciplinary R&D initiatives, and received research awards for publication and patent achievements. Her scholarly impact is reflected by Google Scholar metrics of 68 citations, an h-index of 5, and an i10-index of 2.

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Featured Publications

Synthesis and characterization of natural fibre with ZnO nanocomposites
– International Journal on Interactive Design and Manufacturing, 2023 | Citations: 9

Jiaxiu Wang | Advanced Nanomaterials | Research Excellence Award

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Assoc. Prof. Dr. Jiaxiu Wang | Advanced Nanomaterials | Research Excellence Award

School of Life Sciences and Medical Engineeringng | Anhui University | China

Assoc. Prof. Dr. Jiaxiu Wang is a highly recognized materials scientist whose research advances sustainable polymers, biomass-derived nanomaterials, and functional bio-based composites. With 784 citations, 17 scholarly documents, an h-index of 13, and an i10-index of 13, her work demonstrates strong scientific impact and international recognition in green materials science. Her research focuses on cellulose and chitin nanocrystals, COF-derived carbon materials, hydroplastic polymers, functional nanocomposites, photothermal plastics, and sustainable packaging systems. She has published influential studies in Progress in Materials Science, Nature Sustainability, ACS Nano, Nano Today, and Advanced Energy and Sustainability Research, reporting key innovations such as nanoconfined water–induced transitions, eco-friendly hydrosetting plastics, biomimetic self-assembly, and multifunctional nanocomposite membranes. Her contributions extend to bio-inspired materials, renewable polymers, moisture-induced electric generation, and stimuli-responsive nanoparticles, providing fundamental insights into structure–property relationships and green chemistry. She has authored a book chapter on bio-based gas-barrier materials and actively serves as a reviewer and guest editor for international journals, reflecting her leadership in sustainable materials research and renewable nanotechnologies.

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Featured Publications

Biobased Materials for Food Packaging
– Journal of Bioresources and Bioproducts, 2021 | Ciations: 227
Hydroplastic Polymers as Eco-Friendly Hydrosetting Plastics
– Nature Sustainability, 2021 | Ciations: 125
Warm-White OLEDs with High Power Efficiency and Low Efficiency Roll-Off
– ACS Applied Materials & Interfaces, 2016 | Ciations: 72

Jyothi K R | Advanced Nanomaterials | Best Researcher Award

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Dr. Jyothi K R | Advanced Nanomaterials | Best Researcher Award

Faculty | Vijayanagara Sri Krishnadevaraya University Ballari | India

Dr. Jyothi K R is an emerging researcher in Physics with noteworthy contributions in luminescent nanomaterials, functional nanocomposites, photocatalysis, anti-counterfeiting technologies, and optoelectronic materials. With 88 citations, 13 Scopus-indexed documents and an h-index of 6, her research demonstrates consistent scholarly impact across materials science, nanotechnology, and advanced functional materials. Her work focuses extensively on rare-earth doped silicates, molybdates, and oxide-based nanophosphors for applications spanning white LEDs, radiation sensing, thermoluminescence dosimetry, UV shielding, smart packaging, and environmental remediation. She has authored 20 national and international publications, many appearing in reputable journals such as Ceramics International, Journal of Molecular Structure, Journal of Polymers and the Environment, Inorganic Chemistry Communications, Physica B, and Journal of Solid State Chemistry, with impact factors ranging from 3.5 to 8+. Her studies on LiAlSiO₄, Sr₂MgSi₂O₇, La₂MoO₆, and Y₂MoO₆ nanomaterials have significantly advanced understanding of structure–property relationships, spectroscopic behavior, and multifunctional applications. Dr. Jyothi K R has also contributed to scientific literature through two books on advanced functional nanomaterials and emerging materials properties. Her innovative work includes a filed patent on synthesizing nanocomposites for white LED applications, showcasing her commitment to translational research. Her active involvement in research dissemination includes presenting papers at national and international conferences, where she earned the Best Oral Presentation Award for her work on luminescent nanomaterials. She has also served in editorial and reviewer roles, contributing to peer-review quality and academic scholarship. Her research interests span green synthesis methods, thermoluminescence, dielectric studies, photocatalytic degradation, antimicrobial films, anti-counterfeiting materials, and quantum computational analysis. Dr. Jyothi K R’s research contributions continue to support advancements in sustainable materials, optical engineering, and nanotechnology-driven innovations.

Profiles: Scopus | Google Scholar

Featured Publications

1. Bhagya, K. R., Basavaraj, R. B., Jyothi, K. R., Nagabhushana, H., Murugendrappa, M. V., Gnana Prakash, A. P., Nagabhushana, N. M., & Hegde, V. N. (2021). Dy³⁺ doped Y₂MoO₆ nanopowders for white light emission: Spectroscopic and transport properties for optoelectronic and energy harvesting applications. Colloid and Interface Science Communications, 43, 100447. https://doi.org/10.1016/j.colcom.2021.100447

2. Bhagya, K. R., Jyothi, K. R., Radha Krushna, B. R., Sharma, S. C., Robin Nadar, N., Murugendrappa, M. V., Carounanidy, U., Samanthsinghar, P., Francis, D., & Nagabhushana, H. (2024). Utilization of Aloe vera-infused Sm³⁺ doped La₂MoO₆ nanophosphors: Their role in anti-counterfeiting, white LEDs and transport properties. Ceramics International, 50(6), 9721–9731. https://doi.org/10.1016/j.ceramint.2023.12.290

3. Jyothi, K. R., Bhagya, K. R., Nagabhushana, H., Gnana Prakash, A. P., Murugendrappa, M. V., & Hegde, V. N. (2020). Synthesis and characterization of advanced functional dysprosium doped Sr₂MgSi₂O₇ nanopowders for white LED application. Physica B: Condensed Matter, 590, 412195. https://doi.org/10.1016/j.physb.2020.412195

4. Jyothi, K. R., Bhagya, K. R., Darshan, G. P., Hegde, V. N., Sharma, S. C., & Nagabhushana, N. M. (2021). Phytochemical mediated synthesis of praseodymium-doped beta-eucryptite nanophosphor for ultraviolet-stimulated fluorescence-based unclonable security applications. Inorganic Chemistry Communications, 130, 108671. https://doi.org/10.1016/j.inoche.2021.108671

5. Jyothi, K. R., Bhagya, K. R., Nagabhushana, H., Murugendrappa, M. V., Gnana Prakash, A. P., & Hegde, V. N. (2020). Facile green synthesis, characterization and transport properties of LiAlSiO₄:Ce³⁺ nanocomposites. Ceramics International, 46(7), 9706–9713. https://doi.org/10.1016/j.ceramint.2019.12.238

Jaouad Bensalah | Synthesis and Self Assembly of Nanomaterials | Best Researcher Award

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Prof. Dr. Jaouad Bensalah | Synthesis and Self Assembly of Nanomaterials | Best Researcher Award

Laboratory of Advanced Materials and Process Engineering, Department of Chemistry, Faculty of Sciences | Ibn Tofail University | Morocco

Prof. Dr. Jaouad Bensalah, a distinguished researcher at the Laboratory of Advanced Materials and Process Engineering, Department of Chemistry, Faculty of Sciences, Ibn Tofail University, Morocco, has made significant contributions in materials chemistry, nanocomposites, adsorption science, and corrosion inhibition. With 693 citations, 46 Scopus-indexed publications, and an h-index of 17, his research demonstrates a consistent impact across multidisciplinary fields such as nanotechnology, environmental chemistry, surface science, and process engineering. His scholarly output includes over 40 high-impact papers in Q1 and Q2 journals such as Scientific Reports, Environmental Science and Pollution Research, Inorganic Chemistry Communications, and ACS Omega, focusing on adsorption mechanisms, green corrosion inhibitors, polymeric resins, and nanocomposite synthesis. His works integrate experimental studies with DFT, MD, and MC simulations, advancing theoretical understanding of adsorption thermodynamics and corrosion control. Prof. Dr. Jaouad Bensalah’s research also explores eco-friendly solutions for heavy metal and dye removal, polymer-based adsorbents, and sustainable materials derived from natural and recycled sources. His international collaborations span Germany, Saudi Arabia, Finland, Turkey, Canada, and Qatar, enhancing the global reach of his investigations. He has presented extensively at international conferences including ICMES, I2SM, and CIMAE, highlighting innovative approaches to environmental remediation and materials protection. As a reviewer for MDPI and Hindawi journals and an academic editor for Separations (MDPI) and Atlantic Journal of Life Sciences, he contributes to advancing global research quality. Recognized for his scientific rigor and leadership in nanomaterials and corrosion science, Prof. Dr. Jaouad Bensalah’s research continues to influence the development of sustainable technologies for industrial and environmental applications. His pioneering studies on polymeric ion-exchange resins and eco-corrosion inhibitors mark a significant step toward greener chemistry and materials innovation.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate

Featured Publications

1. Bensalah, J., Berradi, M., Habsaoui, A., Allaoui, M., Essebaai, H., El Khattabi, O., et al. (2021). Kinetic and thermodynamic study of the adsorption of cationic dyes by the cationic artificial resin Amberlite® IRC50. Materials Today: Proceedings, 45, 7468–7472.

2. Bensalah, J., Habsaoui, A., Dagdag, O., Lebkiri, A., Ismi, I., Rifi, E. H., Warad, I., et al. (2021). Adsorption of a cationic dye (Safranin) by artificial cationic resins Amberlite® IRC-50: Equilibrium, kinetic and thermodynamic study. Chemical Data Collections, 35, 100756.

3. El Amri, A., Bensalah, J., Idrissi, A., Lamya, K., Ouass, A., Bouzakraoui, S., et al. (2022). Adsorption of a cationic dye (Methylene bleu) by Typha Latifolia: Equilibrium, kinetic, thermodynamic and DFT calculations. Chemical Data Collections, 38, 100834.

4. Bensalah, J., Benhiba, F., Habsaoui, A., Ouass, A., Zarrouk, A., & Rifi, E. H. (2022). The adsorption mechanism of the anionic and cationic dyes of the cationic resin A®IRC-50: Kinetic study and theoretical investigation using DFT. Journal of the Indian Chemical Society, 100512.

5. Bensalah, J., Idrissi, A., El Faydy, M., Doumane, G., Staoui, A., Hsissou, R., et al. (2023). Investigation of the cationic resin as a potential adsorbent to remove MR and CV dyes: Kinetic, equilibrium isotherms studies and DFT calculations. Journal of Molecular Structure, 1278, 134849.