Your search keyword '"Sarwar, Noman"' showing total 3 results

1. Application of Ternary Nanoparticles in the Heat Transfer of an MHD Non-Newtonian Fluid Flow.

Author

Sarwar, Noman, Jahangir, Saad, Asjad, Muhammad Imran, and Eldin, Sayed M.

Subjects

NON-Newtonian flow (Fluid dynamics), FLUID flow, HEAT transfer, NON-Newtonian fluids, MAGNETOHYDRODYNAMICS, NANOPARTICLES, THERMAL conductivity, NANOFLUIDS

Abstract

This paper introduces a novel theoretical model of ternary nanoparticles for the improvement of heat transmission. Ternary nanoparticles in a heat conductor are shown in this model. Ternary nanoparticles consist of three types of nanoparticles with different physical properties, and they are suspended in a base fluid. Analytical solutions for the temperature and velocity fields are found by using the Laplace transform approach and are modeled by using a novel fractional operator. As a result, the ternary nanoparticles are identified, and an improved heat transfer feature is observed. Further experimental research on ternary nanoparticles is being carried out in anticipation of a faster rate of heat transmission. According to the graphed data, ternary nanoparticles have greater thermal conductivity than that of hybrid nanoparticles. Moreover, the fractional approach based on the Fourier law is a more reliable and efficient way of modeling the heat transfer problem than the artificial approach. The researchers were driven to create a concept of existing nanoparticles in order to boost heat transfer, since there is a strong demand in the industry for a cooling agent with improved heat transfer capabilities. [ABSTRACT FROM AUTHOR]

Published

2022

2. Analysis of Fractional Bioconvection with Hybrid Nanoparticles in Channel Flow.

Author

Asjad, Muhammad Imran, Ikram, Muhammad Danish, Sarwar, Noman, Muhammad, Taseer, Sivasankaran, Sivanadam, and Subaihi, Sami Ahmed Abdu

Subjects

CHANNEL flow, FICK'S laws of diffusion, PROPERTIES of fluids, THERMAL boundary layer, FLUID flow, RAYLEIGH number, RAYLEIGH-Benard convection

Abstract

In this paper, MHD Brinkman-type fluid flow containing titanium dioxide and silver nanoparticle hybrid nanoparticles with generalized Mittag–Leffler kernel-based fractional derivative is investigated in the presence of bioconvection. The governing equations with dimensional analysis and fractional approach are obtained by using the fractional Fourier's law for heat flux and Fick's law for diffusion. As a result, the bioconvection Rayleigh number, which is responsible for the declining in the fluid velocity and fractional parameters used to control the thermal and momentum boundary layers thickness of fluid properties. The obtained solutions can be beneficial for proper analysis of real data and provide a tool for testing possible approximate solutions where needed. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Prabhakar Fractional Approach for the Convection Flow of Casson Fluid across an Oscillating Surface Based on the Generalized Fourier Law.

Author

Sarwar, Noman, Asjad, Muhammad Imran, Sitthiwirattham, Thanin, Patanarapeelert, Nichaphat, and Muhammad, Taseer

Subjects

*FLUID flow, *PROPERTIES of fluids, *UNSTEADY flow, *FREE convection, *VELOCITY

Abstract

In the present work, an unsteady convection flow of Casson fluid, together with an oscillating vertical plate, is examined. The governing PDEs corresponding to velocity and temperature profile are transformed into linear ODEs with the help of the Laplace transform method. The ordinary derivative model generalized to fractional model is based on a generalized Fourier law. The solutions for energy and velocity equations are obtained after making the equations dimensionless. To check the insight of the physical parameters, especially the symmetric behavior of fractional parameters, it is found that for small and large values of time, fluid properties show dual behavior. Since the fractional derivative exhibits the memory of the function at the chosen value of time, therefore the present fractional model is more suitable in exhibiting memory than the classical model. Such results can be useful in the fitting of real data where needed. In the limiting case when fractional parameters are taken β = γ = 0 and α = 1 for both velocity and temperature, we get the solutions obtained with ordinary derivatives from the existing literature. [ABSTRACT FROM AUTHOR]

Published

2021