Impact of generalized heat and mass flux models on Darcy–Forchheimer Williamson nanofluid flow with variable viscosity
In the current study, we analyze the 2D Williamson nanoliquid flow due to variable thickness surface
embedded in permeable space. Cattaneo–Christov heat and mass flux assumptions have been
employed for the embodiment of heat and mass equations. Flow is generated by an exponential
stretchable sheet. The Darcy–Forchheimer model is considered to scrutinize the liquid flow in a
porous medium. The case of prescribed exponential surface temperature of heat transfer is examined.
A model is contrived to comprise the partial differential equations and then transform them into
ordinary differential equations by imposing an appropriate non-dimensional similarity
transformation. The bvp4c technique is used to execute the laborious non-linear equations. A
numerical interpretation is manifested to incorporate the skin friction values. The significance of the
effect on the involved parameters is presented in graphs and discussed in detail.
In the current study, we analyze the 2D Williamson nanoliquid flow due to variable thickness surface
embedded in permeable space. Cattaneo–Christov heat and mass flux assumptions have been…
The core purpose of this work is the formulation of a mathematical model by dint of a
new fractional modeling approach to study the dynamics of flow and heat transfer phenomena.
This…
Modeling and design of on-chip interconnect, the interconnection between the components
is becoming the fundamental roadblock in achieving high-speed integrated circuits. The scaling
…