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Abstract Improving heat transfer in biomedical liquid flows plays a crucial role in enhancing the performance of medical devices, targeted drug delivery systems, and thermal treatment techniques. This research tackles the drawbacks of traditional fluids in complex physiological conditions by employing a nanofluid to enhance the thermal efficiency of peristaltic blood flow. Therefore, radiative bioconvection peristaltic flow of peristaltic flow of Eyring‐Powell nanomaterial is considered. Effects of Joule heating and viscous dissipation are examined in this study. Symmetric channel walls are compliant in nature. A first‐order chemical reaction is present in mass transport. Furthermore, the effects of Brownian diffusion and thermophoresis are thoroughly explained using Buongiorno's model. The formulated complex constitutive equations are transformed into their dimensionless form through suitable similarity transformations and subsequently solved numerically. Velocity, thermal field, concentration, and heat transfer rate through influential variables are graphically visualized. Present attempt relevance in areas like biomedical, engineering, microfluidics, and energy processes, where precise fluid control and heat transfer are critical.
Hussain et al. (Sun,) studied this question.