Electroosmotic flow in ternary (TiO2-SiO2-Al2O3) blood-based sutterby nanomaterials with bio-active mixers

Medical scientists, clinicians, and bioengineers are fascinated in the detection of blood flow pattern through cardiovascular system because it is employed to diagnose the human circulatory disorders such as atherosclerosis. This work is dedicated to the mathematical modeling for the blood flow through human circulatory regimen with electroosmotic force, tri-hybrid nanoparticles, swimming microbes and activation energy. A novel ternary fluid is prepared by dispersing titania, silica, and alumina nanoparticles in pure blood. It is a well-known fact that blood is regarded as incompressible non-Newtonian fluid, due to which Sutterby fluid paradigm is regarded to detect the shear-thinning characteristics of blood precisely. To describe the electroosmotic flow, Poisson-Boltzmann expression is used. The novelty of the appraisal is the incorporation of electroosmotic force on blood flow containing with microbes and three distinct nanoparticles. Appropriate dimension-free variables are utilized to modify the dimensional system into dimension-free version. An unraveller approach, finite-difference is assigned to evaluate the numerical solution of dimensionless system accompanied by stability and convergence. The computed numerical results are sketched versus crucial factors and explored through graphs and tables. Electroosmotic variable enhances the motion of ternary blood nanofluid. Higher exponential heat source variable strengthens the thermal borderline wideness. Heat transport rate is weakened via higher estimation of thermo-migration and random motion variables. Decay in mass transport rate is noticed for thermo-migration factor. Peclet number weakens the motile microbe's density. Bio-active Lewis number strengthens the density number of motile microbes. This study is extremely worthwhile in medical domain such as cancer treatment, heart surgeries, tumor treatment, microbial fuel cells, and microfluidic systems.