Correction
25 Oct 2013: Noreen S, Ahmad B, Hayat T (2013) Correction: Mixed Convection Flow of Nanofluid in Presence of an Inclined Magnetic Field. PLOS ONE 8(10): 10.1371/annotation/8c69b563-486a-4405-b71a-a2caf809ce28. https://doi.org/10.1371/annotation/8c69b563-486a-4405-b71a-a2caf809ce28 View correction
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Abstract
This research is concerned with the mixed convection peristaltic flow of nanofluid in an inclined asymmetric channel. The fluid is conducting in the presence of inclined magnetic field. The governing equations are modelled. Mathematical formulation is completed through long wavelength and low Reynolds number approach. Numerical solution to the nonlinear analysis is made by shooting technique. Attention is mainly focused to the effects of Brownian motion and thermophoretic diffusion of nanoparticle. Results for velocity, temperature, concentration, pumping and trapping are obtained and analyzed in detail.
Citation: Noreen S, Ahmed B, Hayat T (2013) Mixed Convection Flow of Nanofluid in Presence of an Inclined Magnetic Field. PLoS ONE 8(9): e73248. https://doi.org/10.1371/journal.pone.0073248
Editor: Mohammed Yousfi, University Paul Sabatier, France
Received: April 1, 2013; Accepted: July 19, 2013; Published: September 23, 2013
Copyright: © 2013 Noreen et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This paper was funded by the Deanship of Scientific Research (DSR), King Abdulaziz University (KAU), under grant no. 10-130/1433 HiCi. The authors, therefore, acknowledge technical and financial support of KAU. The support is in the form of a project for academic research at KAU. This is to certify that this work is not funded through any external source/research organization including industry, etc. External funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Peristaltic motion is now an important research topic due to its immense applications in engineering and physiology. This type of rhythmic contraction is the basis of peristaltic pumps that move fluids through tubes without direct contact with pump components. This is a particular advantage in biological/medical applications where the pumped material need not to contact any surface except the interior of the tube. The word “peristalsis” comes from a Greek word “Peristaltikos”which means clasping and compressing. The peristaltic flow has specific involvement in the transport of urine from kidney to the bladder, chyme movement in gastrointestinal tract, movement of ovum in the female fallopian tubes, blood circulation in the small blood vessels, roller and finger pumps, sanitary fluid transport and many others. Latham [1] and Shapiro et al. [2] reported initial studies for the peristaltic flow of viscous fluid. Since then ample attempts have been made for peristalsis in symmetric flow configuration (see few recent studies [3]–[8]). On the other hand the physiologists argued that the intra-uterine fluid flow (because of mymometrical contractions) represents peristaltic mechanism and the myometrical contractions may appear in both asymmetric and symmetric channels [9]. Hence some researchers [10]–[15] discussed the peristaltic transport in an asymmetric channel with regard to an application of intra-uterine fluid flow in a nonpregnant uterus.
Heat transfer in cooling processes is quite popular area of research in industry and medical science. Conventional methods for increasing cooling rates include the extended surfaces such as fins and enhancing flow rates. These conventional methods have their own limitations such as undesirable increase in the thermal management system's size and increasing pumping power respectively. The thermal conductivity characteristics of ordinary heat transfer fluids like oil, water and ethylene glycol mixture are not adequate to meet today's requirements. The thermal conductivity of these fluids have key role in heat transfer coefficient between the heat transfer medium and heat transfer surface. Hence many techniques have been proposed for improvement in thermal conductivity of ordinary fluids by suspending nano particles in liquids. The term “nano” introduced by Choi [16] describes a liquid suspension containing ultra-fine particles (diameter less than 50 nm). The nanoparticle can be made of metal, metal oxides, carbide, nitride and even immiscible nano scale liquid droplets. Natural convective boundary-layer flow in a porous medium saturated by a nanofluid is studied by Nield and Kuznetsov [17]. Although the literature on flow of viscous nanofluid has grown during the last few years but the information regarding peristaltic flow of nanofluid is almost nonexistant. For example, Akbar et al. [18] studied the influence of partial slip in peristaltic flow of viscous fluid.
The aim of present study is to venture further in the regime of peristalsis for fluids with nanoparticles. Therefore we examine here the mixed convective peristaltic transport of nanofluid in an inclined asymmetric channel in the presence of inclined magnetic field. Channel asymmetry is produced by peristaltic waves of different amplitude and phases. Mathematical modelling involves the consideration of Brownian motion and thermophorsis effects. Numerical solution of nonlinear problem is obtained using shooting method. Limiting case for nanofluid in symmetric channel is also analyzed. Detailed analysis for the quantities of interest is seen.
Mathematical Formulation
We consider mixed convective viscous nanofluid in an inclined asymmetric channel of width . The fluid is conducting in presence of inclined magnetic field B0 only. Let
be the speed by which sinusoidal waves propagate along the channel walls. The
and
-axes in the rectangular coordinates
system are taken parallel and transverse to the direction of wave propagation. Further the lower wall has temperature
and nanoparticle concentration
while the temperature and nanoparticle concentration at the upper wall are denoted by
and
respectively. The geometry of wall surfaces can be represented as follows:
(1)where
are the wave amplitudes and the phase difference
varies in the range
. The case
is subject to the symmetric channel with waves out of phase and the waves are in phase when
. Here
is the wavelength,
the time and
and
satisfy
. Denoting the velocity components
and
along the
and
directions in the fixed frame, we can represent velocity
in following definition:
(2)
The equations governing the flow under consideration are(3)
(4)
(5)
(6)
(7)in which
is the pressure,
the density of fluid,
the thermophoretic diffusion coefficient, g the acceleration due to gravity, T the temperature,
the concentration,
the thermal conductivity,
the Brownian diffusion coefficient,
the ratio of the specific heat capacity of the nanoparticle material and heat capacity of the fluid,
the thermal diffusivity,
the thermal diffusivity,
the angle of channel inclination,
the channel inclination,
the inclined magnetic field,
the electrical conductivity,
is the density of the particle, and
is the volumetric volume expansion coefficient
The transformations between fixed and wave frames are defined as follows:(8)in which (
) and
are the velocity components and pressure in the wave frame.
We now introduce(9)where
represent the local mass Grashof number, Frude number, Reynolds number, Prandtl number, local temperature Grashof number, Brownian motion parameter, Eckert number and thermophoresis parameter respectively.
Employing transformation (8), dimensionless variables (9) and long wavelength and low Reynolds number approximation, the dimensionless forms of above equations in terms of stream function
(10)
(11)
(12)
(13)where
The dimensionless boundary conditions are given by
(14)with
. The dimensionless time mean flow rate F in the wave frame is related to the dimensionless time mean flow rate
in the laboratory frame by the following expressions
(15)
Results and Discussion
Our main interest in this section is to examine the velocity (u), temperature (), concentration (
) and pressure rise per wavelength (
) for the influence of local Grashof number (
), Frude number (
, mass Grashof number (
), Prandtl number (
), Eckert number (
), Brownian motion parameter (
), Hartman number (
), phase difference parameter (
) and thermophoresis parameter (
.
3.1 Pumping characteristics
This subsection illustrates the behavior of emerging parameters ,
, and
on pressure rise per wavelength
. The dimensionless pressure rise per wavelength versus time-averaged flux
has been plotted in the Figs. 1–3. Here the upper right-hand quadrant
denotes the region of peristalsis pumping, where
(positive pumping) and
(adverse pressure gradient). Quadrant
, where
(favorable pressure gradient) and
(positive pumping), is designated as augmented flow (copumping region). Quadrant
, such that
(adverse pressure gradient) and
, is called retrograde or backward pumping. The flow is opposite to the direction of the peristaltic motion and there is no flow in the last (Quadrant
. There is an inverse linear relation between
and
. Pumping rate decreases by increasing
in pumping region. Figs. 1 and 2 show that
decreases with
and increases with
in all the pumping regions. This is due to the reason that Brownian diffusion is directly related to increased flow rate. It is noticed from Fig. 3 that
increases with
in all the pumping regions by fixing the values of other parameters i.e Mass convection supports pressure rise in pumping region.
3.2 Flow characteristics
The variations of ,
, and
on the velocity have been seen in this subsection. Figs. 4–7 are constructed to serve the purpose. We observe that flow is more slanted towards the lower wall of channel (
) due to the consideration of inclined channel and inclined magnetic field. There is an increase in velocity at the upper wall of the channel when
increases. Fig. 4 depicts that magnitude of the velocity of nanofluid increases at the lower wall of channel, as the values of phase difference increases (
). That is an increase in asymmetry leads to an increase in the fluid velocity at the lower wall of channel. Velocity u is decreasing function of M near the upper half of channel. Figs. 5 and 6 portray the power of temperature and mass Grashof number. Clearly the velocity increases near the lower wall. There is a considerable variation near the walls
and
for
and
. We observe that heat and mass convection supports flow near lower wall due to inclined channel. Increase in
also supports the motion near the upper wall of channel which is shown in Fig. 7. This is due to thermophoretic diffusion.
3.3 Heat transfer characteristics
Effect of heat transfer on peristalsis is shown in the Figs. 8–12. In Fig. 8, we observed the effects of on the temperature profile
by fixing the other parameters. This Fig. indicates that the temperature increases with the increase of
. It is noticed from Figs. 9 and 10 that
increases with
and
by fixing the values of other parameters. Figs. 11 and 12 depict the effects of Brownian motion parameter (
) and thermophoresis parameter (
on the temperature profile. One can observe that the temperature profile is an increasing function of
and
between the walls
and
. Influence of
on
is similar to
at the lower wall.
3.4 Mass transfer characteristics
Influence of mass transfer on peristalsis is shown in the Figs. 13–15. The main parameters influencing the mass transfer include and
. Figs. 13 and 14 depict that the concentration distribution decreases near the lower wall of channel when
and
are increased. Fig. 15 illustrates that the influence of
on
is opposite to
near the upper wall of channel. Since the ratio of momentum diffusivity and thermal diffusivity is inversely proportional to mass distribution.
3.5 Trapping
Trapping phenomenon is shown in Figs. 16–17 for different values of and
respectively. Trapping is an important aspect of peristaltic motion. It is the formation of a bolus of fluid by the closed streamlines. The case
corresponds to trapping in the absence of applied magnetic field. Here we observed that bolus exists in upper part of channel. Later on, as we move towards hydromagnetic flow (increase the values of
a shift towards lower half of channel is observed. Meanwhile size of trapped bolus decreases. Trapping exists for
at the centre of channel. It is observed that number of closed streamlines circulating the bolus reduce in number as we increase the values of mass Grashof number.
Conclusions
A detailed analysis is presented for magnetohydrodynamic peristaltic transport of nanofluid in an inclined asymmetric channel with heat and mass transfer. Numerical simulation is utilized for solution analysis. The critical cases from asymmetric to symmetric channel (), inclined to straight channel (
), inclined hydromagnetic flow to hydromagnetic flow (
) are also discussed. The main findings of the presented study are listed as follows. Pumping rate increases with
and
in all pumping regions. The parabolic nature of velocity distribution is disturbed due to inclined channel. Flow is more slanted towards the lower wall. Magnitude of velocity is larger in an inclined asymmetric channel than symmetric channel. Temperature distribution is an increasing function of Brownian motion parameter (
) and thermophoresis parameter (
).
Author Contributions
Conceived and designed the experiments: SN. Analyzed the data: SN TH. Contributed reagents/materials/analysis tools: SN. Wrote the paper: SN. Provided financial support: BA.
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