Cattaneo-Christov Heat Flux based Darcy-Forchheimer Hybrid Nanofluid Flow with Marangoni Convection above a Permeable Disk
Page: 1-28 (28)
Author: Nalini Kumar Sethy, Debashis Mohanty, Ganeswar Mahanta, Kamala Lochan Mahanta and Sachin Shaw*
DOI: 10.2174/9789815223705124010003
PDF Price: $15
Abstract
The study highlights a rising number of fluids such as nanofluids and hybrid
nanofluids encountered in daily life that exhibit non-Newtonian behavior and they are exploited
in manufacturing due to their high heat transfer rate becoming more and more important as time
goes on. The focus is on hybrid nanomaterials because they increase liquid alloys' and fluids'
thermal conductivity. The various investigations on a thermal Marangoni convective flow of
aluminium alloy and Boehmite alumina nanoparticles into gasoline oil in base fluid water on a
steady Darcy-Forchheimer flow are covered. With the system's exponential heat generation and
viscous dissipation, the thermal impact is more pronounced in the presence of Cattaneo-Christov heat flux. To simplify the highly coupled nonlinear governing equations (PDEs) and
the boundary conditions (BCs), a suitable similarity conversion is being applied. The outcomes
of the conversion equations and their BCs are evaluated by MATLAB bvp4c routine with the
shooting techniques. Through the use of graphs and tables, it has been determined how different
governing factors affect the velocity, temperature, skin friction, and Nusselt number. A quick
comparison between a hybrid nanofluid and a nanofluid is displayed in each graph. We also
discussed the system's Bejan numbers and entropy creation. It has been observed that the
proportion of heat transmission increases with heat generation but decreases with the
Marangoni number. A nonlinear increase in the permeability constant and Brinkman number
results in a rise in entropy generation.
Three-Dimensional Numerical Computational Model for an Unsteady Hybrid Nanofluids Past Stretching MHD Rotating Sheet
Page: 29-52 (24)
Author: Salma Ahmedai*, Precious Sibanda, Sicelo Goqo and Uthman Rufai
DOI: 10.2174/9789815223705124010004
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Abstract
Effects of Activation Energy and ThermoConvection of Nanofluid Flow
Page: 53-63 (11)
Author: Sewli Chatterjee*
DOI: 10.2174/9789815223705124010005
PDF Price: $15
Abstract
Nonlinear mixed convection in magnetohydrodynamic thermo-convection nanofluid
flow is addressed. Flow is induced by a stretched surface. Chemical reaction effects on the
activation energy of the species concentration of Arrhenius are considered. The nonlinear
governing equations are converted to a dimensionless ordinary system through adequate
transformations. The solutions of nonlinear dimensionless expressions are computed by
employing the spectral quasilinearization method. A consequence of various parameters
involved such as velocity, concentration, and thermal field has been reported graphically.
Concentration has the reverse trend for both random motion and thermophoresis variables.
Study of Oblique Nanofluid Flow Past a Stretching Sheet
Page: 64-85 (22)
Author: Vikas Poply*, Shilpa Taneja and Parveen Kumar
DOI: 10.2174/9789815223705124010006
PDF Price: $15
Abstract
The analysis of impinging oblique nano-fluid past a stretching sheet is done in the
current communication. The nanoparticles' behaviour in fluids for convective heat transfer has
been extensively studied. We assume that the fluid and the stretching velocity change linearly.
In this paper, we used a cutting-edge Genetic Algorithm technique to better understand how a
nanofluid's thermal characteristics and heat transport vary over time. Additionally, the impact
of a change in the fluid's impinging angle is investigated. The temperature and concentration
curves, skin friction coefficient, and Nusselt number have all been observed and graphically
displayed.
Effect of Casson Nanofluid's Outer Velocity with Melting Heat Transmission beyond a Stretching Sheet
Page: 86-93 (8)
Author: Vikas Poply*, Sabyasachi Mondal and Parveen Kumar
DOI: 10.2174/9789815223705124010007
PDF Price: $15
Abstract
An analysis was conducted to observe the collective consequence of the melting
procedure across a stretching sheet in a Casson nanofluid with outer velocity. The outcomes of
melting heat parameter (M) and Casson parameter (β) are shown in this analysis. The leading
PDEs are moulded in ODE with similarity variables. The numerical results of moulded ODE
are given by the RKF scheme with shooting procedures. Important parameters of the nanofluid
are examined and graphically displayed. Tables are used to display the Sherwood number,
Nusselt number, and skin friction coefficient based on different nanofluid characteristics. The
development of cooling systems that raise the heat transmission belongings of nanofluids and
increase engineering potential will be greatly aided by this research.
Dual Solutions of Magneto-Radiative Ag-Water Nanofluid Slip Flow Across the Porous Medium Due to a Permeable Contracting Surface with Heat Generation: Stability Analysis
Page: 94-115 (22)
Author: Gopinath Mandal*
DOI: 10.2174/9789815223705124010008
PDF Price: $15
Abstract
The current study looks at the heat transfer of a magneto-radiative nanofluid over an
exponentially contracting permeable sheet in the existence of heat generation with numerous
slip boundary constraints. It also looks at the stability and duality of solutions. Here, a waterbased fluid with silver (Ag) nanoparticles is employed. Before being computed by bvp4c in the
Matlab program, the governing nonlinear partial differential equations are converted into
dimensionless nonlinear ODEs via a similarity transformation. Due to the contracting surface
scenario, a dual-nature solution can only be found if a sufficient suction value is used. We may
infer from stability investigation that the first one is stable while the second one is unstable. A
stable solution makes sense with the least positive eigenvalues, but a lower unstable solution
indicates negative eigenvalues. The Nusselt number and the skin-friction factor may be
improved by increases in the silver nanoparticle’s solid volume percentage. The least
eigenvalue converges to zero as the suction and contracting surface parameters reach their
critical values. Nanofluids that are magnetic and radiative can be used to create beautiful and
effective electromagnetic devices, including in the areas of clothing, paper, plastics, food
colorants, cars, cancer therapy, medicines, ceramics, soaps, and paints.
Spectral Quasi-Linearization Method for Thixotropic Nanofluid Passing through a Stretching Surface with Activation Energy
Page: 116-130 (15)
Author: Anwesha Dingal, Puspita Mondal, Anindya Kundu, Sharmistha Ghosh and Hiranmoy Mondal*
DOI: 10.2174/9789815223705124010009
PDF Price: $15
Abstract
The primary goal of the current investigation is to understand the thixotropic
nanofluid’s magnetohydrodynamic (MHD) nonlinear convective flow. The implementation of
appropriate transformations allows for the transition of sets of ordinary differential equations
from partial differential systems. Spectral Quasi-Linearization Method (SQLM) is applied to
solve these ODEs. Further study has been performed in order to establish a model for
nanomaterials containing thermophoresis phenomena and Brownian motion. Graphs are used
to depict and discuss the effects caused due to numerous quantities of fluid flow, temperature,
environment, and nanoparticle concentration. In addition to this, the local Nusselt number, the
skin friction coefficient, as well as the Sherwood number's numerical values, are determined
and examined. Some interesting observations on velocity, heat, and concentration have been
observed due to the variation made in thixotropic parameters and other allied parameters such
as thermophoresis and Brownian motion.
Effect of MHD Viscous Nanofluid Flow in the Presence of Internal Heat Generation
Page: 131-146 (16)
Author: Nibedita Mandal, Sewli Chatterjee and Hiranmoy Mondal*
DOI: 10.2174/9789815223705124010010
PDF Price: $15
Abstract
In this current study, we investigated the boundary layer steady nanofluid flow which
is viscous. Utilizing the spectral quasi-linearization method (SQLM), the mathematical model
has been solved. To analyze the convergence of the numerical method, we calculated the
residual errors that are approximately less by [10-8
]. The local Sherwood number, the
coefficient of the rate of heat transfer, and the local drag force coefficient along with various
flow parameters are analyzed numerically and graphically. The influence of thermophoresis
and Brownian motion has also been discussed briefly.
Subject Index
Page: 147-151 (5)
Author: Sabyasachi Mondal*
DOI: 10.2174/9789815223705124010011
PDF Price: $15
Introduction
Computational simulation and experimental techniques for nanofluid flow is a collection of studies on nanofluid modelling. It brings together eight detailed research articles that describe the latest developments in nanofluid flow experimentation and simulation. Topics covered include numerical flow simulations and applications on MHD viscous nanofluid, bioconvective nanofluid, oblique nanofluid, Casson nanofluid, hybrid nanofluid, Darcy-Forchheimer hybrid nanofluid, magneto-radiative Ag-water nanofluid, and thixotropic nanofluid. Key Features - Includes eight chapters authored by experts in fluid mechanics and numerical simulation - Showcases significant and novel attempts on computational simulation modelling for developing new mathematical models on nanofluids at the research level - Highlights current research intended to advance mathematics and other areas of science and technology - Includes references for advanced readers This publication is essential for researchers and students, academicians who are learning nanofluid flow models. Readers involved in applied research and development projects involving nanofluids will also benefit from the information (environmentalists, technicians and biomedical engineers).