Dr. Nisha Shukla’s research is centered on the mathematical modeling and analytical study of nanofluid dynamics, with a strong emphasis on heat and mass transfer processes influenced by magnetic, thermal, and radiative effects. Her doctoral research involved the application of the Homotopy Analysis Method (HAM) to transport phenomena in nanofluids, contributing novel insights into predicting multiple solutions and conducting entropy generation analysis in complex fluid systems. A key aspect of her work involves studying hybrid and ternary nanofluids, which are essential for improving the thermal performance of advanced energy systems and microfluidic devices. Her analytical approaches provide a deeper understanding of nonlinear behaviors, second-law thermodynamics, and flow stability under various physical conditions.

Dr. Shukla has published over a dozen peer-reviewed research articles in high-impact journals such as Physics Letters A, European Physical Journal Plus, and Communications in Nonlinear Science and Numerical Simulation. Her collaborations with eminent international researchers, including Prof. Ioan Pop and Dr. O.A. Bég, reflect the global relevance of her work. Her research findings are of particular interest to interdisciplinary fields such as computational fluid dynamics, thermal engineering, and materials science.

In addition to academic contributions, Dr. Shukla has delivered expert lectures, participated in international conferences, and served as a committee member in multiple mathematical science events. Through her research, she continues to contribute meaningfully to the development of sustainable and efficient fluid flow models, aiding in the advancement of energy and material technologies.