Abstract
Researchers have commonly known non-Newtonian materials for their extensive technical and industrial uses including coal slurries, clay mixture, food dispensing, paper manufacturing, nutritional preparation, wiring coatings, polymers, cosmetics, oil recovery, rubber, crystal growth and plastic sheeting. The goal of presented research is to analyze bioconvectional second-grade nanoliquid flow with implications of thermal conductivity and motile microorganism across three-dimensional sheet. A transmuted construction is formed in the ordinary differential method by the use of suitable similarity functions. Governing relations of present flow problem are presented graphically and solved numerically by utilizing built-in MATLAB computational tool with the help of the famed numerical shooting method bvp4c (Lobatto IIIa Formula). The influences of physical parameters like activation energy parameter, bioconvection Lewis number, Lewis number, Peclet number, thermophoresis number, mixed convective number, buoyancy ratio number and Brownian motion number via the velocity profile, temperature concentration, volumetric concentration and motile concentration are discussed in detail. The current research has major applications in medical, contemporary aerospace technologies and importance to energy systems. The results designate that
x-
component of skin friction is enhanced for larger values of bioconvection Rayleigh number by 25%. The
y-
component of skin friction is enhanced for larger values of mixed convection parameter by 10%. Furthermore, local Nusselt number is upgraded for growing values of thermal Biot parameter by 57%.