In this paper, the mechanism of radiative Walter's B nanofluid on a rotational cone under magnetic regime is examined. Time-dependent fluid flow caused by cone rotation includes implication theoretically and practically in engineering and applied sciences. Additionally, interesting characteristics of thermophoresis, Brownian motion, and chemical reactions are examined. Self-similar solutions are obtained by treating angular velocity as an inverse linear function of period toward too far from the cone. The Runge–Kutta–Fehlberg fourth–fifth procedure was used to replicate the performance of the course visually and obtain the numerical result of a reduced nonlinear system. Comparing the acquired result to previously published material is another significant aspect of the current investigation that serves to verify the outcome. The Brownian motion parameter is found to have conflicting influences on heat and mass transfer rates, along with temperature and concentration fields. The existence of chemical reactions, according to the research, may be more beneficial in developing reaction processes.
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