Noor Zeb Khan | Nanotechnology and Materials Science | Editorial Board Member

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Dr. Noor Zeb Khan | Nanotechnology and Materials Science | Editorial Board Member

Lecturer | Air University Islamabad | Pakistan

Dr. Noor Zeb Khan is an active researcher in Computational Fluid Dynamics (CFD), Nanotechnology, and Materials Science, contributing extensively to advanced numerical modeling and simulation. With 33 SCI-indexed publications and a cumulative impact factor of 106.50, his research is widely recognized, supported by 187 Scopus citations, 23 documents, and an h-index of 7 (Scopus) and 9 (Google Scholar). His work spans fluid–structure interaction, nanofluid dynamics, heat and mass transfer, magnetohydrodynamics (MHD), porous media flows, and hybrid numerical–AI methodologies integrating FEM, ANN, LBM, and COMSOL/MATLAB-based modeling. Dr. Noor Zeb Khan has produced influential research on wake dynamics, flow interference, and entropy generation analysis, including recent open-access studies such as his lattice Boltzmann investigation of dual rectangular cylinders and his FEM–ANN hybrid modeling of magnetized wavy enclosures. His findings contribute to improving predictive accuracy in thermal systems, microfluidic engineering, and energy-transport applications. He has delivered impactful contributions through high-quality journal publications, computational modelling advancements, and methodological innovations in machine-learning-assisted numerical simulations. His scholarly achievements include research awards, peer recognition, and growing citation influence. Dr. Noor Zeb Khan also provides reviewer services for multiple international SCI journals, supporting the advancement of CFD, applied mathematics, and nanofluid research communities. His ongoing work focuses on developing high-fidelity multiphysics models, optimizing thermo-hydrodynamic systems, and advancing smart computational frameworks that integrate physics-based solvers with artificial intelligence for next-generation engineering solutions.

Profiles: Scopus | ORCID | Google Scholar | Sci Profiles

Featured Publications

1. Bilal, S., Shah, M. I., Khan, N. Z., Akgül, A., & Nisar, K. S. (2022). Onset about non-isothermal flow of Williamson liquid over exponential surface by computing numerical simulation in perspective of Cattaneo–Christov heat flux theory. Alexandria Engineering Journal, 61(8), 6139–6150.

2. Shah, I. A., Bilal, S., Akgül, A., Omri, M., Bouslimi, J., & Khan, N. Z. (2022). Significance of cold cylinder in heat control in power law fluid enclosed in isosceles triangular cavity generated by natural convection: A computational approach. Alexandria Engineering Journal, 61(9), 7277–7290.

3. Bilal, S., Khan, N. Z., Shah, I. A., Awrejcewicz, J., Akgül, A., & Riaz, M. B. (2022). Numerical study of natural convection of power law fluid in a square cavity fitted with a uniformly heated T-fin. Mathematics, 10(3), 342.

4. Khan, N. Z., Bilal, S., Kolsi, L., Shflot, A. S., & Malik, M. Y. (2024). A case study on entropy generation in MHD nanofluid flow in L-shaped triangular corrugated permeable enclosure. Case Studies in Thermal Engineering, 59, 104487.

5. Khan, N. Z., Mahmood, R., Bilal, S., Akgül, A., Abdullaev, S., Mahmoud, E. E., … (2023). Mixed convective thermal transport in a lid-driven square enclosure with square obstacle. Alexandria Engineering Journal, 64, 981–998.

 

Lei Fan | Nanotechnology and Materials Science | Editorial Board Member

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Dr. Lei Fan | Nanotechnology and Materials Science | Editorial Board Member

Master Tutor | School of Civil Engineering and Architecture, Zhejiang University of Science & Technology | China

Dr. Lei Fan is an emerging researcher in nano-mechanics and micro-/nano-scale structural behavior, with a strong focus on the mechanical effects, transport phenomena, and interfacial interactions of advanced nanomaterials. His work integrates atomic-scale modeling, computational materials science, and solid–liquid interface mechanics to address fundamental questions in graphene, hexagonal boron nitride (h-BN), and hybrid two-dimensional (2D) systems. With 289 Scopus citations, 41 publications, and an h-index of 10, he has established a growing impact in the fields of materials science and civil engineering nanotechnology. Dr. Lei Fan has authored 38 peer-reviewed papers, including 25 SCI-indexed publications as first or corresponding author, demonstrating strong leadership in scholarly communication. His notable works include high-impact contributions to International Journal of Molecular Sciences (Q1, IF~6.2) on ion/water molecular transport in angstrom-scale channels, offering fundamental insights that bridge atomic modeling with solid–liquid interaction mechanisms. His research in Surfaces and Interfaces (Q1, IF~6.1) examines toughness enhancement strategies in 2D hybrid materials via carbon nanotube integration, advancing design principles for next-generation nanocomposites. He has also published multiple studies in Diamond and Related Materials on grain boundaries, nanoholes, functional groups, and defect evolution in graphene/h-BN heterostructures, providing systematic understanding of bonding energies, deformation mechanisms, and temperature-dependent interface transitions. Dr. Lei Fan’s research excellence is reinforced through competitive funding support, including the Natural Science Foundation of Zhejiang Province, institutional scientific research grants, and participation in China’s State Key Program of the National Natural Science Foundation. His contributions extend to scholarly service as an editorial board member of Journal of Materials and New Energy and an active reviewer for leading SCI journals such as 2D Materials, Nanotechnology, and Computational Materials Science. With sustained innovation across atomic-scale mechanics, defect engineering, and nano-interface behavior, Dr. Lei Fan’s work continues to shape the theoretical and computational foundation of next-generation micro-/nano-structured materials.

Profiles: Scopus | ORCID | ResearchGate

Featured Publications

1. Fan, L. (2023). Mechanical mechanism of ion and water molecular transport through angstrom-scale graphene derivatives channels: From atomic model to solid-liquid interaction. International Journal of Molecular Sciences, 23, 1433.

2. Fan, L., Cai, X., Wang, H., Ye, J., Hong, Y., & Ying, J. (2023). Toughening two-dimensional hybrid materials by integrating carbon nanotubes. Surfaces and Interfaces, 36, 102559.

3. Fan, L., Bian, Z., Huang, Z., Song, F., Xia, Y., & Xu, J. (2022). Role of grain boundary and nanoholes in geometrical deformation and bonding energies of graphene/hexagonal boron nitride. Diamond and Related Materials, 126, 109119.

4. Fan, L., Bian, Z., Huang, Z., Song, F., Xia, Y., & Xu, J. (2022). New insight into bonding energy and stress distribution of graphene oxide/hexagonal boron nitride: Functional group and grain boundary effect. Diamond and Related Materials, 127, 109185.

5. Fan, L., & Yao, W. (2022). Temperature dependence of interfacial bonding and configuration transition in graphene/hexagonal boron nitride containing grain boundaries and functional groups. International Journal of Molecular Sciences, 23, 1433.