Analysis of Gold -- blood nanoparticles in a wavy tube in the presence
of MHD and wall properties.
The current analytical examination supports nanofluids with peristaltic
flow motion in a confined length of non-uniform horizontal tube with an
endoscope using Buongiorno’s nanofluid model. The consideration based on
three geometries of Gold –blood MHD nanoparticles (sphere, cylinders
and blades) in addition to wall properties, thermal and velocity slip
affects. This model is studied for biomedical applications in various
fields. Equations and boundary conditions are modeled and formed in some
dimensionless control equations for the realistic study of the model.
Exact solutions with nanoparticle shape effects on temperature,
velocity, heat transfer and stream function expression are obtained.
Visual depiction for these solutions under the study of variation of
various parameters are demonstrated. Few observations illustrate that
platelet shape nanoparticles attain highest thermal conductivity.
Maximum and increasing behavior of temperature experienced for sphere
shape nanoparticles and for higher values of thermal slip parameter.
Increasing conduct of velocity profile is also seen for large values of
velocity slip parameter and sphere shape nanoparticles shows dominance
as compared to brick and platelet shape particles. Trapping phenomenon
is also discussed for the desirability of present study. Design of micro
peristaltic pump for the transport of nanofluids and drug delivery
system that offers various drug geometries are the main use of this