Rate My Professor Abhik Majumdar

Abhik Majumder serves as an Assistant Professor in the Department of Mechanical Engineering at the National Institute of Technology Agartala. His research specializes in heat transfer, numerical simulation, and multiphase flow, with additional interests in numerical fluid flow, passive cooling, and related thermal sciences. Majumder's work encompasses experimental and numerical studies on phenomena such as Taylor bubble flow in mini-channels, drop formation dynamics, pool boiling heat transfer using nanofluids, and heat exchanger performance enhancements. He has contributed to projects including a SERB-funded initiative in mechanical engineering alongside colleagues at NIT Agartala. His PhD thesis, completed in 2019 at IIT Kharagpur, focused on the formation and evolution of liquid droplets and direct contact condensation of vapour bubbles in an immiscible liquid.

Majumder has authored or co-authored 18 publications documented on institutional profiles. Notable works include 'Role of nanomaterials and surfactants for the preparation of graphene nanofluid: a review' (Materials Today: Proceedings, 2021), 'Local Nusselt number enhancement during gas–liquid Taylor bubble flow in a square mini-channel: An experimental study' (International Journal of Thermal Sciences, 2013), 'Dynamics of drop formation, growth and pinching phenomena from a submerged nozzle' (Chemical Engineering Science, 2021), 'Numerical study of fin-tube type heat exchanger with delta winglets' (Frontiers in Heat and Mass Transfer, 2016), 'Fabrication of nano-copper surfaces by thermal evaporation technique to investigate nucleate pool boiling heat transfer performance of R-141b' (Materials Today: Proceedings, 2022), 'Effect of corner radius of a T-junction mini-square channel on fluid flow and heat transfer in the developing region: A three dimensional numerical simulation' (Procedia Engineering, 2015), and 'Performance study of continuous helical baffle shell and tube heat exchanger with central low-pressure regions' (Journal of Thermal Science and Engineering Applications, 2016). These contributions advance understanding in thermal management, nanofluid applications, and microscale flow behaviors.