Your search keyword '"Sajid Tanveer"' showing total 3 results

1. Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge

Author

Tag El Din El Sayed M., Sajid Tanveer, Jamshed Wasim, Shah Syed Zahir Hussain, Eid Mohamed R., Ayub Assad, Guedri Kamel, Sánchez-Chero Manuel, Chero José Antonio Sánchez, Barco Gilberto Carrión, and Maquen-Niño Gisella Luisa Elena

Subjects

inclined magnetized flow, infinite shear rate viscosity, brownian motion, 2-d cross fluid, melting process of energy, thermophoresis diffusion, Physics, QC1-999

Abstract

This demonstration of study focalizes the melting transport and inclined magnetizing effect of cross fluid with infinite shear rate viscosity along the Skan-Falkner wedge. Transport of energy analysis is brought through the melting process and velocity distribution is numerically achieved under the influence of the inclined magnetic dipole effect. Moreover, this study brings out the numerical effect of the process of thermophoresis diffusion and Brownian motion. The infinite shear rate of viscosity model of cross fluid reveals the set of partial differential equations (PDEs). Similarity transformation of variables converts the PDEs system into nonlinear ordinary differential equations (ODEs). Furthermore, a numerical bvp4c process is imposed on these resultant ODEs for the pursuit of a numerical solution. From the debate, it is concluded that melting process cases boost the velocity of fluid and velocity ratio parameter. The augmentation of the minimum value of energy needed to activate or energize the molecules or atoms to activate the chemical reaction boosts the concentricity.

Published

2022

2. Stratified heat transfer of magneto-tangent hyperbolic bio-nanofluid flow with gyrotactic microorganisms: Keller-Box solution technique

Author

Shahzad Faisal, Jamshed Wasim, Sajid Tanveer, Nisar Kottakkaran Sooppy, Isa Siti Suzilliana Putri Mohamed, Edacherian Abhilash, and Saleel C. Ahamed

Subjects

gyrotactic microorganisms, nanofluids, stratification, mhd, stretchable sheet, keller-box method, Physics, QC1-999

Abstract

The purpose of the present investigation is to examine the heat, mass and microorganism concentration transfer rates in the magnetohydrodynamics (MHD) stratified boundary layer flow of tangent hyperbolic nanofluid past a linearly, uniform stretching surface comprising gyrotactic microorganisms as well as nanoparticles. The governing PDEs with relevant end point conditions are molded into a non-dimensional ordinary differential equation (ODE) form by means of the similarity transformation. The numerical solution of dimensionless problem is acquired within the frame of robust Keller-Box technique. The velocity, temperature, mass and motile microorganism density are investigated graphically within the context of different significant parameters. Numerical results have been inspected via plots and table (namely as the local Nusselt number, the local wall mass flux and the local microorganisms wall flux). This article proves that the energy, concentration and motile microorganism density reduce with increase in thermal, solutal and motile density stratification parameters. The asserted outcomes are beneficial to enhance the cooling and heating processes, energy generation, thermal machines, solar energy systems, industrial processes etc.

Published

2021

3. Impact of double-diffusive convection and motile gyrotactic microorganisms on magnetohydrodynamics bioconvection tangent hyperbolic nanofluid

Author

Sajid Tanveer, Sagheer Muhammad, Hussain Shafqat, and Shahzad Faisal

Subjects

magnetohydrodynamics, bioconvection, gyrotactic microorganisms, nanofluid, magnetic field, keller box method, stretching sheet, double diffusion, Physics, QC1-999

Abstract

The double-diffusive tangent hyperbolic nanofluid containing motile gyrotactic microorganisms and magnetohydrodynamics past a stretching sheet is examined. By adopting the scaling group of transformation, the governing equations of motion are transformed into a system of nonlinear ordinary differential equations. The Keller box scheme, a finite difference method, has been employed for the solution of the nonlinear ordinary differential equations. The behaviour of the working fluid against various parameters of physical nature has been analyzed through graphs and tables. The behaviour of different physical quantities of interest such as heat transfer rate, density of the motile gyrotactic microorganisms and mass transfer rate is also discussed in the form of tables and graphs. It is found that the modified Dufour parameter has an increasing effect on the temperature profile. The solute profile is observed to decay as a result of an augmentation in the nanofluid Lewis number.

Published

2020