Nadeem Abbas | Nanotechnology | Editorial Board Member

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Dr. Nadeem Abbas | Nanotechnology | Editorial Board Member

Researcher | Prince Sultan University | Saudi Arabia

Dr. N. Abbas is a distinguished researcher recognized for his pioneering contributions to fluid mechanics, heat transfer, and nanofluid dynamics, with a strong focus on hybrid nanofluids, magnetohydrodynamics (MHD), nonlinear stretching surfaces, and microscale thermal phenomena. His research emphasizes the development of advanced mathematical and computational models to analyze complex flow behaviors relevant to modern engineering and biomedical systems. With an extensive publication record in leading international journals such as Chinese Journal of Physics, Computer Methods and Programs in Biomedicine, Results in Physics, and International Communications in Heat and Mass Transfer, Dr. Abbas has established himself as an influential figure in applied mathematics and thermofluid sciences. His most cited works on MHD hybrid nanofluid flow over nonlinear stretching cylinders, hybrid-based nanofluid flow over curved surfaces, and three-dimensional stagnation point flows have collectively garnered over 800 citations, reflecting his significant academic impact. Integrating analytical, numerical, and simulation-based approaches, Dr. Abbas’s research addresses key challenges in energy systems, materials processing, and biomedical fluid modeling, fostering international collaborations across the Middle East and Asia that advance the understanding of hybrid nanofluid applications for enhanced heat transfer and optimized fluid performance. His recent studies on nonlinear modeling of hybrid nanofluid flows over permeable and thermally slipping surfaces provide valuable insights into sustainable energy systems and industrial cooling processes. Through his innovative research and globally recognized publications, Dr. Abbas continues to contribute substantially to computational physics, applied mathematics, and mechanical engineering, driving progress in smart materials and nanofluid technologies with profound scientific and societal relevance.

Profiles : Google Schalor

Featured Publications

  1. Abbas, N., Nadeem, S., Saleem, A., Malik, M. Y., Issakhov, A., & Alharbi, F. M. (2021). Models base study of inclined MHD of hybrid nanofluid flow over nonlinear stretching cylinder. Chinese Journal of Physics, 69, 109–117.
    Cited by: 235

  2. Nadeem, S., Abbas, N., & Malik, M. Y. (2020). Inspection of hybrid based nanofluid flow over a curved surface. Computer Methods and Programs in Biomedicine, 189, 105193.
    Cited by: 228

  3. Nadeem, S., Abbas, N., & Khan, A. U. (2018). Characteristics of three-dimensional stagnation point flow of hybrid nanofluid past a circular cylinder. Results in Physics, 8, 829–835.
    Cited by: 155

  4. Abbas, N., Saleem, S., Nadeem, S., Alderremy, A. A., & Khan, A. U. (2018). On stagnation point flow of a micropolar nanofluid past a circular cylinder with velocity and thermal slip. Results in Physics, 9, 1224–1232.
    Cited by: 122

  5. Abbas, N., Rehman, K. U., Shatanawi, W., & Malik, M. Y. (2022). Numerical study of heat transfer in hybrid nanofluid flow over permeable nonlinear stretching curved surface with thermal slip. International Communications in Heat and Mass Transfer, 135, 106107.
    Cited by: 108

Dr. N. Abbas’s research on hybrid nanofluid dynamics and magnetohydrodynamics has significantly advanced the understanding of thermal and flow transport phenomena, enabling innovations in energy efficiency, biomedical engineering, and sustainable industrial processes. His work bridges fundamental science and practical application, fostering global progress in advanced materials and fluid technologies.

Yasmina Khane | Nanotechnology | Best Researcher Award

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Assoc. Prof. Dr. Yasmina Khane | Nanotechnology | Best Researcher Award

Associate Professor | University of Ghardaia | Algeria

Dr. Yasmina Khane, affiliated with the Université de Ghardaia in Algeria, is an accomplished researcher whose work bridges the disciplines of materials chemistry, environmental science, and nanotechnology. Her research primarily explores the synthesis, characterization, and functional applications of nanostructured materials particularly metal and metal oxide nanoparticles in catalysis, environmental remediation, and sustainable energy systems.Dr. Khane’s investigations have made notable contributions to green nanotechnology, especially through the development of phyto-synthesized nanoparticles using plant extracts as eco-friendly reducing agents. Her recent study on silver nanoparticles synthesized via Cotula cinerea extract highlights her commitment to sustainable materials science. This work demonstrated the potential of bio-fabricated nanomaterials in enhancing salt tolerance in wheat (Triticum durum), emphasizing agricultural resilience and plant-environment interactions under stress conditions.A central theme in her research is photocatalysis the design and optimization of semiconductor-based catalysts for pollutant degradation and energy-related reactions. Dr. Khane has synthesized and investigated photocatalytic systems such as ZnO-impregnated biomaterials and Cu₂NiSnS₄ thin films, which have shown remarkable efficiency in degrading organic contaminants like dyes and pharmaceutical residues. Her publications in journals such as Scientific Reports, Inorganic Chemistry Communications, and Reaction Kinetics, Mechanisms and Catalysis reflect her depth in reaction kinetics, surface chemistry, and materials modification.With over 657 citations, 34 publications, and an h-index of 12, Dr. Khane has established herself as an influential figure in applied chemical research. Her interdisciplinary collaborations with over 150 co-authors underscore a strong international research network. She continually integrates chemistry, physics, and biology to advance eco-conscious technologies for water purification, soil protection, and renewable energy conversion.Overall, Dr. Khane’s scientific portfolio demonstrates a commitment to environmental sustainability through the innovative use of nanostructured catalysts and green synthesis methods. Her work contributes meaningfully to the global pursuit of cleaner technologies, reflecting the synergy between nanoscience, catalysis, and environmental protection.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

  1. Fenniche, F., Khane, Y., Hafsi, Z., Farhat, M., Aouf, D., & Alarbi, F. (2025). Photo catalytic degradation of Coomassie Brilliant Blue using a ternary Polyaniline/Fe₂O₃/Graphene nanocomposite under visible light. Sebha University Conference Proceedings, 103–109.

  2. Daoud, M., Khane, Y., Aouf, D., Benturki, O., Girods, P., Rogaume, Y., & Fontana, S. (2025). Efficient removal of malachite green using modified Algerian date palm spikelet: Characterization, design of experiment (Box–Behnken), density functional theory analysis. Reaction Kinetics, Mechanisms and Catalysis, 1–27.

  3. Kesbi, B., Salhi, N., Khane, Y., Albukhaty, S., Addad, A., Abideen, Z., Alsufyani, H., … (2025). Potential effect of phyto-synthesized silver nanoparticles using Cotula cinerea Del raw extract on salt tolerance of wheat seeds (Triticum durum desf., Boussellam variety). Scientific Reports, 15(1), 28061. Citations: 1

  4. Farhat, M., Al Madani, M. A., Abdullah, T., Embaya, M., Saeed, A., Saleh, A., … (2025). Evaluation of the physical properties of local wheat husk ash and its effects on the compressive strength of hardened cement paste. Discover Chemistry, 2(1), 89.

  5. Nezzari, A., Medina, S., Khane, Y., Boublenza, H., Guezzoul, M., Zoukel, A., … (2025). Synthesis, properties, and photocatalytic degradation of Brilliant Green dye using Cu₂NiSnS₄ thin films under ultraviolet irradiation. Inorganic Chemistry Communications, 174, 114021. Citations: 3

Dr. Yasmina Khane’s research advances sustainable nanotechnology through eco-friendly materials and photocatalysis, offering innovative solutions for environmental purification, agricultural resilience, and renewable energy. Her work bridges science and society, driving global progress toward a cleaner and greener future.