Mr. Kalu Ram Sharma | Fluid Dynamics | Best Scholar Award

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Mr. Kalu Ram Sharma | Fluid Dynamics | Best Scholar Award

Research Scholar | University of Rajasthan | India

Mr. Kalu Ram Sharma is a dedicated scholar and educator in mathematics whose expertise strongly aligns with Fluid Dynamics, as reflected in his academic background, teaching experience, and impactful research. With advanced qualifications in mathematics, he has served as a lecturer at multiple institutions, demonstrating excellence in guiding undergraduate and postgraduate students, while his professional journey highlights a deep commitment to education and research. His primary research interests center on mathematical modeling, magnetohydrodynamics, and nonlinear flow problems, with a consistent focus on Fluid Dynamics, where he has published several notable works in reputed international journals and presented at esteemed conferences. Mr. Sharma’s achievements include clearing prestigious national eligibility and fellowship examinations with strong ranks, underscoring his academic caliber, and his awards and honors reflect recognition of his scholarly merit. His research skills extend to numerical analysis, spectral methods, and computational simulations, which have enhanced his ability to contribute significantly to the study of Fluid Dynamics. Throughout his journey, his continuous participation in workshops and conferences has enriched his perspective, while his perseverance and analytical acumen demonstrate his potential as a researcher. The integration of theory and application in his work on Fluid Dynamics highlights his vision to solve complex mathematical and physical challenges. In conclusion, Mr. Kalu Ram Sharma emerges as a highly motivated academic and researcher whose focus on Fluid Dynamics not only defines his career but also positions him as a valuable contributor to advancing knowledge in applied mathematics and related interdisciplinary domains.

Profile: ORCID

Featured Publications

1. Sharma, K. R., & Jain, S. (2025). Activation energy and radiation effects on MHD Walters-B nanofluid flow over a stretching surface: Spectral analysis. Thermal Advances, 100055.

2. Jain, S., & Sharma, K. R. (2025). Numerical analysis of MHD Casson fluid with non-linear mixed and bio-convection over a non-linear vertical stretching sheet, considering multiple slip and suction/injection effects. Thermal Advances, 100034.

3. Sharma, K. R., & Jain, S. (2025). Study of mixed radiative MHD Cross nanofluid flow over a stretching/contracting sheet in porous medium using Arrhenius activation energy, Newtonian heating and Joule Heating. Thermal Advances, 100021.

4. Sharma, K. R., & Jain, S. (2024). An unsteady MHD Williamson fluid flow in a vertical porous channel with porous media and thermal radiation. International Journal of Advances in Engineering Sciences and Applied Mathematics.

5. Sharma, K. R., & Jain, S. (2024). A numerical study of MHD nonlinear mixed convection flow over a nonlinear vertical stretching sheet with the buoyancy and suction/injection effects. Numerical Heat Transfer, Part B: Fundamentals.

Dr. Tanya Gupta | Computational Fluid Dynamics | Women Researcher Award

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Dr. Tanya Gupta | Computational Fluid Dynamics | Women Researcher Award

Assistant Professor | GLA University | India

Dr. Tanya Gupta is an accomplished academic in Mathematics with expertise in Computational Fluid Dynamics, where her research has extensively focused on heat and mass transfer, hybrid nanofluids, and numerical simulation techniques. She holds a Ph.D. in Mathematics from G.B. Pant University of Agriculture and Technology with her thesis centered on Computational Fluid Dynamics applications, following a master’s and bachelor’s degree in Mathematics from Kumaun University. Professionally, she has served as a Teaching Assistant at G.B. Pant University and currently works as an Assistant Professor at GLA University, Mathura, where she actively teaches Engineering Mathematics, Applied Mathematics, Engineering Calculus, Linear Algebra, and Differential Equations, integrating Computational Fluid Dynamics concepts in her academic approach. Her research interests strongly revolve around Computational Fluid Dynamics, supported by publications in reputed SCI journals, book chapters, and participation in international and national conferences. She has secured prestigious achievements such as CSIR NET JRF, GATE qualification, and the INSPIRE Fellowship, highlighting her academic excellence. Dr. Tanya Gupta has demonstrated research skills in advanced mathematical modeling, Legendre wavelet collocation techniques, nanofluid dynamics, and Computational Fluid Dynamics simulations. She is also actively engaged in professional societies, workshops, and international collaborations enhancing Computational Fluid Dynamics studies. Recognized with several honors, she also contributes administratively at GLA University in examination management, departmental branding, and academic advising. In conclusion, Dr. Tanya Gupta is a dedicated researcher and educator whose career is strongly shaped by her contributions in Computational Fluid Dynamics, making her a significant asset to her institution and the broader scientific community, with Computational Fluid Dynamics serving as the core foundation of her academic and professional identity. Her Google Scholar citations 135, h-index 6, i10-index 4, showcasing measurable research impact.

Profile: Google Scholar

Featured Publications

1. Gupta, T., Pandey, A. K., & Kumar, M. (2024). Numerical study for temperature-dependent viscosity based unsteady flow of GP-MoS2/C2H6O2-H2O over a porous stretching sheet. Numerical Heat Transfer, Part A: Applications, 85(7), 1063–1084.

2. Gupta, T., Pandey, A. K., & Kumar, M. (2024). Effect of Thompson and Troian slip on CNT-Fe3O4/kerosene oil hybrid nanofluid flow over an exponential stretching sheet with Reynolds viscosity model. Modern Physics Letters B, 38(02), 2350209.

3. Upreti, H., Pandey, A. K., Gupta, T., & Upadhyay, S. (2023). Exploring the nanoparticle's shape effect on boundary layer flow of hybrid nanofluid over a thin needle with quadratic Boussinesq approximation: Legendre wavelet approach. Journal of Thermal Analysis and Calorimetry, 148(22).

4. Gupta, T., Pandey, A. K., & Kumar, M. (2024). Shape factor and temperature-dependent viscosity analysis for the unsteady flow of magnetic AlO–TiOCHO–HO using Legendre wavelet technique. Pramana, 98(2), 73.

5. Gupta, T., Kumar, M., Yaseen, M., & Rawat, S. K. (2025). Heat transfer of MHD flow of hybrid nanofluid (SWCNT-MWCNT/C3H8O2) over a permeable surface with Cattaneo–Christov model. Numerical Heat Transfer, Part B: Fundamentals, 86(3), 436–451.