Numerical computation of melting heat transfer in nonlinear radiative flow of hybrid nanofluids due to permeable stretching curved surface

The current study investigates the hydro-magnetic transport of hybrid nanoliquids by a permeable extendable curved sheet. Furthermore, the Lorentz force properties that cause magnetic field interaction with the motion of nanoliquid are investigated. To examine the flow's thermodynamic integrity, thermally radiation and heat sink/source are included. The obtained expressions are computed by using RK-4 approach and data indicates differences for both the hybrid nanoliquids and conventional nanoliquid. Tables and graphs are used to investigate the impact of relevant numbers on the flow fields. To the best of our knowledge, no such research that sheds light on the aforementioned concerns has been submitted yet. As a result, we believe that our one-of-a-kind technique will serve as a foundation for gathering vital information from such flow, therefore assisting with a variety of technological difficulties.

Automated summary

The study investigates the hydro-magnetic transport of hybrid nanoliquids using a permeable extendable curved sheet, analyzing the Lorentz force properties and including considerations for thermally radiation. The obtained expressions were computed using the RK-4 approach and differences between hybrid nanoliquids and conventional nanoliquid were observed, with tables and graphs used to study the impact of relevant numbers on flow fields. No such research addressing these concerns has been submitted yet, and the unique technique is believed to lay the foundation for gathering vital information and assisting with technological difficulties.